Merge branch 'dev' into nvds-new-espnow

This commit is contained in:
NP v/d Spek 2024-11-15 13:48:12 +01:00 committed by GitHub
commit 5a02435c79
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46 changed files with 1522 additions and 193 deletions

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@ -219,7 +219,7 @@ jobs:
. venv/bin/activate
pytest -vv --cov-report=xml --tb=native tests
- name: Upload coverage to Codecov
uses: codecov/codecov-action@v4
uses: codecov/codecov-action@v5
with:
token: ${{ secrets.CODECOV_TOKEN }}

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@ -204,11 +204,11 @@ void BME68xBSEC2Component::update_subscription_() {
}
void BME68xBSEC2Component::run_() {
this->op_mode_ = this->bsec_settings_.op_mode;
int64_t curr_time_ns = this->get_time_ns_();
if (curr_time_ns < this->next_call_ns_) {
if (curr_time_ns < this->bsec_settings_.next_call) {
return;
}
this->op_mode_ = this->bsec_settings_.op_mode;
uint8_t status;
ESP_LOGV(TAG, "Performing sensor run");
@ -219,57 +219,60 @@ void BME68xBSEC2Component::run_() {
ESP_LOGW(TAG, "Failed to fetch sensor control settings (BSEC2 error code %d)", this->bsec_status_);
return;
}
this->next_call_ns_ = this->bsec_settings_.next_call;
if (this->bsec_settings_.trigger_measurement) {
bme68x_get_conf(&bme68x_conf, &this->bme68x_);
switch (this->bsec_settings_.op_mode) {
case BME68X_FORCED_MODE:
bme68x_get_conf(&bme68x_conf, &this->bme68x_);
bme68x_conf.os_hum = this->bsec_settings_.humidity_oversampling;
bme68x_conf.os_temp = this->bsec_settings_.temperature_oversampling;
bme68x_conf.os_pres = this->bsec_settings_.pressure_oversampling;
bme68x_set_conf(&bme68x_conf, &this->bme68x_);
bme68x_conf.os_hum = this->bsec_settings_.humidity_oversampling;
bme68x_conf.os_temp = this->bsec_settings_.temperature_oversampling;
bme68x_conf.os_pres = this->bsec_settings_.pressure_oversampling;
bme68x_set_conf(&bme68x_conf, &this->bme68x_);
this->bme68x_heatr_conf_.enable = BME68X_ENABLE;
this->bme68x_heatr_conf_.heatr_temp = this->bsec_settings_.heater_temperature;
this->bme68x_heatr_conf_.heatr_dur = this->bsec_settings_.heater_duration;
// status = bme68x_set_op_mode(this->bsec_settings_.op_mode, &this->bme68x_);
status = bme68x_set_heatr_conf(BME68X_FORCED_MODE, &this->bme68x_heatr_conf_, &this->bme68x_);
status = bme68x_set_op_mode(BME68X_FORCED_MODE, &this->bme68x_);
this->op_mode_ = BME68X_FORCED_MODE;
ESP_LOGV(TAG, "Using forced mode");
break;
case BME68X_PARALLEL_MODE:
if (this->op_mode_ != this->bsec_settings_.op_mode) {
bme68x_get_conf(&bme68x_conf, &this->bme68x_);
bme68x_conf.os_hum = this->bsec_settings_.humidity_oversampling;
bme68x_conf.os_temp = this->bsec_settings_.temperature_oversampling;
bme68x_conf.os_pres = this->bsec_settings_.pressure_oversampling;
bme68x_set_conf(&bme68x_conf, &this->bme68x_);
switch (this->bsec_settings_.op_mode) {
case BME68X_FORCED_MODE:
this->bme68x_heatr_conf_.enable = BME68X_ENABLE;
this->bme68x_heatr_conf_.heatr_temp = this->bsec_settings_.heater_temperature;
this->bme68x_heatr_conf_.heatr_dur = this->bsec_settings_.heater_duration;
this->bme68x_heatr_conf_.heatr_temp_prof = this->bsec_settings_.heater_temperature_profile;
this->bme68x_heatr_conf_.heatr_dur_prof = this->bsec_settings_.heater_duration_profile;
this->bme68x_heatr_conf_.profile_len = this->bsec_settings_.heater_profile_len;
this->bme68x_heatr_conf_.shared_heatr_dur =
BSEC_TOTAL_HEAT_DUR -
(bme68x_get_meas_dur(BME68X_PARALLEL_MODE, &bme68x_conf, &this->bme68x_) / INT64_C(1000));
status = bme68x_set_op_mode(this->bsec_settings_.op_mode, &this->bme68x_);
status = bme68x_set_heatr_conf(BME68X_FORCED_MODE, &this->bme68x_heatr_conf_, &this->bme68x_);
status = bme68x_set_op_mode(BME68X_FORCED_MODE, &this->bme68x_);
this->op_mode_ = BME68X_FORCED_MODE;
this->sleep_mode_ = false;
ESP_LOGV(TAG, "Using forced mode");
status = bme68x_set_heatr_conf(BME68X_PARALLEL_MODE, &this->bme68x_heatr_conf_, &this->bme68x_);
break;
case BME68X_PARALLEL_MODE:
if (this->op_mode_ != this->bsec_settings_.op_mode) {
this->bme68x_heatr_conf_.enable = BME68X_ENABLE;
this->bme68x_heatr_conf_.heatr_temp_prof = this->bsec_settings_.heater_temperature_profile;
this->bme68x_heatr_conf_.heatr_dur_prof = this->bsec_settings_.heater_duration_profile;
this->bme68x_heatr_conf_.profile_len = this->bsec_settings_.heater_profile_len;
this->bme68x_heatr_conf_.shared_heatr_dur =
BSEC_TOTAL_HEAT_DUR -
(bme68x_get_meas_dur(BME68X_PARALLEL_MODE, &bme68x_conf, &this->bme68x_) / INT64_C(1000));
status = bme68x_set_heatr_conf(BME68X_PARALLEL_MODE, &this->bme68x_heatr_conf_, &this->bme68x_);
status = bme68x_set_op_mode(BME68X_PARALLEL_MODE, &this->bme68x_);
this->op_mode_ = BME68X_PARALLEL_MODE;
this->sleep_mode_ = false;
ESP_LOGV(TAG, "Using parallel mode");
}
break;
case BME68X_SLEEP_MODE:
if (!this->sleep_mode_) {
bme68x_set_op_mode(BME68X_SLEEP_MODE, &this->bme68x_);
this->sleep_mode_ = true;
ESP_LOGV(TAG, "Using sleep mode");
}
break;
}
status = bme68x_set_op_mode(BME68X_PARALLEL_MODE, &this->bme68x_);
this->op_mode_ = BME68X_PARALLEL_MODE;
ESP_LOGV(TAG, "Using parallel mode");
}
break;
case BME68X_SLEEP_MODE:
if (this->op_mode_ != this->bsec_settings_.op_mode) {
bme68x_set_op_mode(BME68X_SLEEP_MODE, &this->bme68x_);
this->op_mode_ = BME68X_SLEEP_MODE;
ESP_LOGV(TAG, "Using sleep mode");
}
break;
}
if (this->bsec_settings_.trigger_measurement && this->bsec_settings_.op_mode != BME68X_SLEEP_MODE) {
uint32_t meas_dur = 0;
meas_dur = bme68x_get_meas_dur(this->op_mode_, &bme68x_conf, &this->bme68x_);
ESP_LOGV(TAG, "Queueing read in %uus", meas_dur);

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@ -113,13 +113,11 @@ class BME68xBSEC2Component : public Component {
struct bme68x_heatr_conf bme68x_heatr_conf_;
uint8_t op_mode_; // operating mode of sensor
bool sleep_mode_;
bsec_library_return_t bsec_status_{BSEC_OK};
int8_t bme68x_status_{BME68X_OK};
int64_t last_time_ms_{0};
uint32_t millis_overflow_counter_{0};
int64_t next_call_ns_{0};
std::queue<std::function<void()>> queue_;

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@ -6,7 +6,104 @@ namespace dfplayer {
static const char *const TAG = "dfplayer";
void DFPlayer::next() {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing next track");
this->send_cmd_(0x01);
}
void DFPlayer::previous() {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing previous track");
this->send_cmd_(0x02);
}
void DFPlayer::play_mp3(uint16_t file) {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing file %d in mp3 folder", file);
this->send_cmd_(0x12, file);
}
void DFPlayer::play_file(uint16_t file) {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing file %d", file);
this->send_cmd_(0x03, file);
}
void DFPlayer::play_file_loop(uint16_t file) {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing file %d in loop", file);
this->send_cmd_(0x08, file);
}
void DFPlayer::play_folder_loop(uint16_t folder) {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing folder %d in loop", folder);
this->send_cmd_(0x17, folder);
}
void DFPlayer::volume_up() {
ESP_LOGD(TAG, "Increasing volume");
this->send_cmd_(0x04);
}
void DFPlayer::volume_down() {
ESP_LOGD(TAG, "Decreasing volume");
this->send_cmd_(0x05);
}
void DFPlayer::set_device(Device device) {
ESP_LOGD(TAG, "Setting device to %d", device);
this->send_cmd_(0x09, device);
}
void DFPlayer::set_volume(uint8_t volume) {
ESP_LOGD(TAG, "Setting volume to %d", volume);
this->send_cmd_(0x06, volume);
}
void DFPlayer::set_eq(EqPreset preset) {
ESP_LOGD(TAG, "Setting EQ to %d", preset);
this->send_cmd_(0x07, preset);
}
void DFPlayer::sleep() {
this->ack_reset_is_playing_ = true;
ESP_LOGD(TAG, "Putting DFPlayer to sleep");
this->send_cmd_(0x0A);
}
void DFPlayer::reset() {
this->ack_reset_is_playing_ = true;
ESP_LOGD(TAG, "Resetting DFPlayer");
this->send_cmd_(0x0C);
}
void DFPlayer::start() {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Starting playback");
this->send_cmd_(0x0D);
}
void DFPlayer::pause() {
this->ack_reset_is_playing_ = true;
ESP_LOGD(TAG, "Pausing playback");
this->send_cmd_(0x0E);
}
void DFPlayer::stop() {
this->ack_reset_is_playing_ = true;
ESP_LOGD(TAG, "Stopping playback");
this->send_cmd_(0x16);
}
void DFPlayer::random() {
this->ack_set_is_playing_ = true;
ESP_LOGD(TAG, "Playing random file");
this->send_cmd_(0x18);
}
void DFPlayer::play_folder(uint16_t folder, uint16_t file) {
ESP_LOGD(TAG, "Playing file %d in folder %d", file, folder);
if (folder < 100 && file < 256) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x0F, (uint8_t) folder, (uint8_t) file);
@ -29,7 +126,7 @@ void DFPlayer::send_cmd_(uint8_t cmd, uint16_t argument) {
this->sent_cmd_ = cmd;
ESP_LOGD(TAG, "Send Command %#02x arg %#04x", cmd, argument);
ESP_LOGV(TAG, "Send Command %#02x arg %#04x", cmd, argument);
this->write_array(buffer, 10);
}
@ -101,9 +198,37 @@ void DFPlayer::loop() {
ESP_LOGV(TAG, "Nack");
this->ack_set_is_playing_ = false;
this->ack_reset_is_playing_ = false;
if (argument == 6) {
ESP_LOGV(TAG, "File not found");
this->is_playing_ = false;
switch (argument) {
case 0x01:
ESP_LOGE(TAG, "Module is busy or uninitialized");
break;
case 0x02:
ESP_LOGE(TAG, "Module is in sleep mode");
break;
case 0x03:
ESP_LOGE(TAG, "Serial receive error");
break;
case 0x04:
ESP_LOGE(TAG, "Checksum incorrect");
break;
case 0x05:
ESP_LOGE(TAG, "Specified track is out of current track scope");
this->is_playing_ = false;
break;
case 0x06:
ESP_LOGE(TAG, "Specified track is not found");
this->is_playing_ = false;
break;
case 0x07:
ESP_LOGE(TAG, "Insertion error (an inserting operation only can be done when a track is being played)");
break;
case 0x08:
ESP_LOGE(TAG, "SD card reading failed (SD card pulled out or damaged)");
break;
case 0x09:
ESP_LOGE(TAG, "Entered into sleep mode");
this->is_playing_ = false;
break;
}
break;
case 0x41:
@ -113,12 +238,13 @@ void DFPlayer::loop() {
this->ack_set_is_playing_ = false;
this->ack_reset_is_playing_ = false;
break;
case 0x3D: // Playback finished
case 0x3D:
ESP_LOGV(TAG, "Playback finished");
this->is_playing_ = false;
this->on_finished_playback_callback_.call();
break;
default:
ESP_LOGD(TAG, "Command %#02x arg %#04x", cmd, argument);
ESP_LOGV(TAG, "Received unknown cmd %#02x arg %#04x", cmd, argument);
}
this->sent_cmd_ = 0;
this->read_pos_ = 0;

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@ -23,64 +23,30 @@ enum Device {
TF_CARD = 2,
};
// See the datasheet here:
// https://github.com/DFRobot/DFRobotDFPlayerMini/blob/master/doc/FN-M16P%2BEmbedded%2BMP3%2BAudio%2BModule%2BDatasheet.pdf
class DFPlayer : public uart::UARTDevice, public Component {
public:
void loop() override;
void next() {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x01);
}
void previous() {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x02);
}
void play_mp3(uint16_t file) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x12, file);
}
void play_file(uint16_t file) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x03, file);
}
void play_file_loop(uint16_t file) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x08, file);
}
void next();
void previous();
void play_mp3(uint16_t file);
void play_file(uint16_t file);
void play_file_loop(uint16_t file);
void play_folder(uint16_t folder, uint16_t file);
void play_folder_loop(uint16_t folder) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x17, folder);
}
void volume_up() { this->send_cmd_(0x04); }
void volume_down() { this->send_cmd_(0x05); }
void set_device(Device device) { this->send_cmd_(0x09, device); }
void set_volume(uint8_t volume) { this->send_cmd_(0x06, volume); }
void set_eq(EqPreset preset) { this->send_cmd_(0x07, preset); }
void sleep() {
this->ack_reset_is_playing_ = true;
this->send_cmd_(0x0A);
}
void reset() {
this->ack_reset_is_playing_ = true;
this->send_cmd_(0x0C);
}
void start() {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x0D);
}
void pause() {
this->ack_reset_is_playing_ = true;
this->send_cmd_(0x0E);
}
void stop() {
this->ack_reset_is_playing_ = true;
this->send_cmd_(0x16);
}
void random() {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x18);
}
void play_folder_loop(uint16_t folder);
void volume_up();
void volume_down();
void set_device(Device device);
void set_volume(uint8_t volume);
void set_eq(EqPreset preset);
void sleep();
void reset();
void start();
void pause();
void stop();
void random();
bool is_playing() { return is_playing_; }
void dump_config() override;

View file

@ -65,6 +65,9 @@ void ESP32BLETracker::setup() {
[this](ota::OTAState state, float progress, uint8_t error, ota::OTAComponent *comp) {
if (state == ota::OTA_STARTED) {
this->stop_scan();
for (auto *client : this->clients_) {
client->disconnect();
}
}
});
#endif

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@ -24,9 +24,10 @@ I2SAudioSpeaker = i2s_audio_ns.class_(
"I2SAudioSpeaker", cg.Component, speaker.Speaker, I2SAudioOut
)
CONF_BUFFER_DURATION = "buffer_duration"
CONF_DAC_TYPE = "dac_type"
CONF_I2S_COMM_FMT = "i2s_comm_fmt"
CONF_NEVER = "never"
i2s_dac_mode_t = cg.global_ns.enum("i2s_dac_mode_t")
INTERNAL_DAC_OPTIONS = {
@ -73,8 +74,12 @@ BASE_SCHEMA = (
.extend(
{
cv.Optional(
CONF_TIMEOUT, default="500ms"
CONF_BUFFER_DURATION, default="500ms"
): cv.positive_time_period_milliseconds,
cv.Optional(CONF_TIMEOUT, default="500ms"): cv.Any(
cv.positive_time_period_milliseconds,
cv.one_of(CONF_NEVER, lower=True),
),
}
)
.extend(cv.COMPONENT_SCHEMA)
@ -116,4 +121,6 @@ async def to_code(config):
else:
cg.add(var.set_dout_pin(config[CONF_I2S_DOUT_PIN]))
cg.add(var.set_i2s_comm_fmt(config[CONF_I2S_COMM_FMT]))
cg.add(var.set_timeout(config[CONF_TIMEOUT]))
if config[CONF_TIMEOUT] != CONF_NEVER:
cg.add(var.set_timeout(config[CONF_TIMEOUT]))
cg.add(var.set_buffer_duration(config[CONF_BUFFER_DURATION]))

View file

@ -13,21 +13,22 @@
namespace esphome {
namespace i2s_audio {
static const size_t DMA_BUFFER_SIZE = 512;
static const uint8_t DMA_BUFFER_DURATION_MS = 15;
static const size_t DMA_BUFFERS_COUNT = 4;
static const size_t FRAMES_IN_ALL_DMA_BUFFERS = DMA_BUFFER_SIZE * DMA_BUFFERS_COUNT;
static const size_t RING_BUFFER_SAMPLES = 8192;
static const size_t TASK_DELAY_MS = 10;
static const size_t TASK_DELAY_MS = DMA_BUFFER_DURATION_MS * DMA_BUFFERS_COUNT / 2;
static const size_t TASK_STACK_SIZE = 4096;
static const ssize_t TASK_PRIORITY = 23;
static const size_t I2S_EVENT_QUEUE_COUNT = DMA_BUFFERS_COUNT + 1;
static const char *const TAG = "i2s_audio.speaker";
enum SpeakerEventGroupBits : uint32_t {
COMMAND_START = (1 << 0), // Starts the main task purpose
COMMAND_STOP = (1 << 1), // stops the main task
COMMAND_STOP_GRACEFULLY = (1 << 2), // Stops the task once all data has been written
MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE = (1 << 5), // Locks the ring buffer when not set
COMMAND_START = (1 << 0), // starts the speaker task
COMMAND_STOP = (1 << 1), // stops the speaker task
COMMAND_STOP_GRACEFULLY = (1 << 2), // Stops the speaker task once all data has been written
STATE_STARTING = (1 << 10),
STATE_RUNNING = (1 << 11),
STATE_STOPPING = (1 << 12),
@ -91,9 +92,7 @@ static const std::vector<int16_t> Q15_VOLUME_SCALING_FACTORS = {
void I2SAudioSpeaker::setup() {
ESP_LOGCONFIG(TAG, "Setting up I2S Audio Speaker...");
if (this->event_group_ == nullptr) {
this->event_group_ = xEventGroupCreate();
}
this->event_group_ = xEventGroupCreate();
if (this->event_group_ == nullptr) {
ESP_LOGE(TAG, "Failed to create event group");
@ -199,23 +198,17 @@ size_t I2SAudioSpeaker::play(const uint8_t *data, size_t length, TickType_t tick
this->start();
}
// Wait for the ring buffer to be available
uint32_t event_bits =
xEventGroupWaitBits(this->event_group_, SpeakerEventGroupBits::MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE, pdFALSE,
pdFALSE, pdMS_TO_TICKS(TASK_DELAY_MS));
size_t bytes_written = 0;
if ((this->state_ == speaker::STATE_RUNNING) && (this->audio_ring_buffer_.use_count() == 1)) {
// Only one owner of the ring buffer (the speaker task), so the ring buffer is allocated and no other components are
// attempting to write to it.
if (event_bits & SpeakerEventGroupBits::MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE) {
// Ring buffer is available to write
// Lock the ring buffer, write to it, then unlock it
xEventGroupClearBits(this->event_group_, SpeakerEventGroupBits::MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE);
size_t bytes_written = this->audio_ring_buffer_->write_without_replacement((void *) data, length, ticks_to_wait);
xEventGroupSetBits(this->event_group_, SpeakerEventGroupBits::MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE);
return bytes_written;
// Temporarily share ownership of the ring buffer so it won't be deallocated while writing
std::shared_ptr<RingBuffer> temp_ring_buffer = this->audio_ring_buffer_;
bytes_written = temp_ring_buffer->write_without_replacement((void *) data, length, ticks_to_wait);
}
return 0;
return bytes_written;
}
bool I2SAudioSpeaker::has_buffered_data() const {
@ -246,10 +239,12 @@ void I2SAudioSpeaker::speaker_task(void *params) {
const ssize_t bytes_per_sample = audio_stream_info.get_bytes_per_sample();
const uint8_t number_of_channels = audio_stream_info.channels;
const size_t dma_buffers_size = FRAMES_IN_ALL_DMA_BUFFERS * bytes_per_sample * number_of_channels;
const size_t dma_buffers_size = DMA_BUFFERS_COUNT * DMA_BUFFER_DURATION_MS * this_speaker->sample_rate_ / 1000 *
bytes_per_sample * number_of_channels;
const size_t ring_buffer_size =
this_speaker->buffer_duration_ms_ * this_speaker->sample_rate_ / 1000 * bytes_per_sample * number_of_channels;
if (this_speaker->send_esp_err_to_event_group_(
this_speaker->allocate_buffers_(dma_buffers_size, RING_BUFFER_SAMPLES * bytes_per_sample))) {
if (this_speaker->send_esp_err_to_event_group_(this_speaker->allocate_buffers_(dma_buffers_size, ring_buffer_size))) {
// Failed to allocate buffers
xEventGroupSetBits(this_speaker->event_group_, SpeakerEventGroupBits::ERR_ESP_NO_MEM);
this_speaker->delete_task_(dma_buffers_size);
@ -258,9 +253,6 @@ void I2SAudioSpeaker::speaker_task(void *params) {
if (this_speaker->send_esp_err_to_event_group_(this_speaker->start_i2s_driver_())) {
// Failed to start I2S driver
this_speaker->delete_task_(dma_buffers_size);
} else {
// Ring buffer is allocated, so indicate its can be written to
xEventGroupSetBits(this_speaker->event_group_, SpeakerEventGroupBits::MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE);
}
if (!this_speaker->send_esp_err_to_event_group_(this_speaker->reconfigure_i2s_stream_info_(audio_stream_info))) {
@ -270,8 +262,10 @@ void I2SAudioSpeaker::speaker_task(void *params) {
bool stop_gracefully = false;
uint32_t last_data_received_time = millis();
bool tx_dma_underflow = false;
while ((millis() - last_data_received_time) <= this_speaker->timeout_) {
while (!this_speaker->timeout_.has_value() ||
(millis() - last_data_received_time) <= this_speaker->timeout_.value()) {
event_group_bits = xEventGroupGetBits(this_speaker->event_group_);
if (event_group_bits & SpeakerEventGroupBits::COMMAND_STOP) {
@ -281,12 +275,18 @@ void I2SAudioSpeaker::speaker_task(void *params) {
stop_gracefully = true;
}
i2s_event_t i2s_event;
while (xQueueReceive(this_speaker->i2s_event_queue_, &i2s_event, 0)) {
if (i2s_event.type == I2S_EVENT_TX_Q_OVF) {
tx_dma_underflow = true;
}
}
size_t bytes_to_read = dma_buffers_size;
size_t bytes_read = this_speaker->audio_ring_buffer_->read((void *) this_speaker->data_buffer_, bytes_to_read,
pdMS_TO_TICKS(TASK_DELAY_MS));
if (bytes_read > 0) {
last_data_received_time = millis();
size_t bytes_written = 0;
if ((audio_stream_info.bits_per_sample == 16) && (this_speaker->q15_volume_factor_ < INT16_MAX)) {
@ -307,15 +307,13 @@ void I2SAudioSpeaker::speaker_task(void *params) {
if (bytes_written != bytes_read) {
xEventGroupSetBits(this_speaker->event_group_, SpeakerEventGroupBits::ERR_ESP_INVALID_SIZE);
}
tx_dma_underflow = false;
last_data_received_time = millis();
} else {
// No data received
if (stop_gracefully) {
if (stop_gracefully && tx_dma_underflow) {
break;
}
i2s_zero_dma_buffer(this_speaker->parent_->get_port());
}
}
} else {
@ -326,7 +324,6 @@ void I2SAudioSpeaker::speaker_task(void *params) {
xEventGroupSetBits(this_speaker->event_group_, SpeakerEventGroupBits::STATE_STOPPING);
i2s_stop(this_speaker->parent_->get_port());
i2s_driver_uninstall(this_speaker->parent_->get_port());
this_speaker->parent_->unlock();
@ -334,7 +331,7 @@ void I2SAudioSpeaker::speaker_task(void *params) {
}
void I2SAudioSpeaker::start() {
if (this->is_failed() || this->status_has_error())
if (!this->is_ready() || this->is_failed() || this->status_has_error())
return;
if ((this->state_ == speaker::STATE_STARTING) || (this->state_ == speaker::STATE_RUNNING))
return;
@ -402,8 +399,8 @@ esp_err_t I2SAudioSpeaker::allocate_buffers_(size_t data_buffer_size, size_t rin
return ESP_ERR_NO_MEM;
}
if (this->audio_ring_buffer_ == nullptr) {
// Allocate ring buffer
if (this->audio_ring_buffer_.use_count() == 0) {
// Allocate ring buffer. Uses a shared_ptr to ensure it isn't improperly deallocated.
this->audio_ring_buffer_ = RingBuffer::create(ring_buffer_size);
}
@ -419,6 +416,8 @@ esp_err_t I2SAudioSpeaker::start_i2s_driver_() {
return ESP_ERR_INVALID_STATE;
}
int dma_buffer_length = DMA_BUFFER_DURATION_MS * this->sample_rate_ / 1000;
i2s_driver_config_t config = {
.mode = (i2s_mode_t) (this->i2s_mode_ | I2S_MODE_TX),
.sample_rate = this->sample_rate_,
@ -427,7 +426,7 @@ esp_err_t I2SAudioSpeaker::start_i2s_driver_() {
.communication_format = this->i2s_comm_fmt_,
.intr_alloc_flags = ESP_INTR_FLAG_LEVEL1,
.dma_buf_count = DMA_BUFFERS_COUNT,
.dma_buf_len = DMA_BUFFER_SIZE,
.dma_buf_len = dma_buffer_length,
.use_apll = this->use_apll_,
.tx_desc_auto_clear = true,
.fixed_mclk = I2S_PIN_NO_CHANGE,
@ -448,7 +447,8 @@ esp_err_t I2SAudioSpeaker::start_i2s_driver_() {
}
#endif
esp_err_t err = i2s_driver_install(this->parent_->get_port(), &config, 0, nullptr);
esp_err_t err =
i2s_driver_install(this->parent_->get_port(), &config, I2S_EVENT_QUEUE_COUNT, &this->i2s_event_queue_);
if (err != ESP_OK) {
// Failed to install the driver, so unlock the I2S port
this->parent_->unlock();
@ -502,16 +502,7 @@ esp_err_t I2SAudioSpeaker::reconfigure_i2s_stream_info_(audio::AudioStreamInfo &
}
void I2SAudioSpeaker::delete_task_(size_t buffer_size) {
if (this->audio_ring_buffer_ != nullptr) {
xEventGroupWaitBits(this->event_group_,
MESSAGE_RING_BUFFER_AVAILABLE_TO_WRITE, // Bit message to read
pdFALSE, // Don't clear the bits on exit
pdTRUE, // Don't wait for all the bits,
portMAX_DELAY); // Block indefinitely until a command bit is set
this->audio_ring_buffer_.reset(); // Deallocates the ring buffer stored in the unique_ptr
this->audio_ring_buffer_ = nullptr;
}
this->audio_ring_buffer_.reset(); // Releases onwership of the shared_ptr
if (this->data_buffer_ != nullptr) {
ExternalRAMAllocator<uint8_t> allocator(ExternalRAMAllocator<uint8_t>::ALLOW_FAILURE);

View file

@ -7,6 +7,7 @@
#include <driver/i2s.h>
#include <freertos/event_groups.h>
#include <freertos/queue.h>
#include <freertos/FreeRTOS.h>
#include "esphome/components/audio/audio.h"
@ -22,11 +23,12 @@ namespace i2s_audio {
class I2SAudioSpeaker : public I2SAudioOut, public speaker::Speaker, public Component {
public:
float get_setup_priority() const override { return esphome::setup_priority::LATE; }
float get_setup_priority() const override { return esphome::setup_priority::PROCESSOR; }
void setup() override;
void loop() override;
void set_buffer_duration(uint32_t buffer_duration_ms) { this->buffer_duration_ms_ = buffer_duration_ms; }
void set_timeout(uint32_t ms) { this->timeout_ = ms; }
void set_dout_pin(uint8_t pin) { this->dout_pin_ = pin; }
#if SOC_I2S_SUPPORTS_DAC
@ -117,10 +119,14 @@ class I2SAudioSpeaker : public I2SAudioOut, public speaker::Speaker, public Comp
TaskHandle_t speaker_task_handle_{nullptr};
EventGroupHandle_t event_group_{nullptr};
uint8_t *data_buffer_;
std::unique_ptr<RingBuffer> audio_ring_buffer_;
QueueHandle_t i2s_event_queue_;
uint32_t timeout_;
uint8_t *data_buffer_;
std::shared_ptr<RingBuffer> audio_ring_buffer_;
uint32_t buffer_duration_ms_;
optional<uint32_t> timeout_;
uint8_t dout_pin_;
bool task_created_{false};

View file

@ -180,7 +180,7 @@ void LD2420Component::apply_config_action() {
}
void LD2420Component::factory_reset_action() {
ESP_LOGCONFIG(TAG, "Setiing factory defaults...");
ESP_LOGCONFIG(TAG, "Setting factory defaults...");
if (this->set_config_mode(true) == LD2420_ERROR_TIMEOUT) {
ESP_LOGE(TAG, "LD2420 module has failed to respond, check baud rate and serial connections.");
this->mark_failed();

View file

@ -25,6 +25,8 @@ from .const import (
CONF_MODBUS_CONTROLLER_ID,
CONF_OFFLINE_SKIP_UPDATES,
CONF_ON_COMMAND_SENT,
CONF_ON_ONLINE,
CONF_ON_OFFLINE,
CONF_REGISTER_COUNT,
CONF_REGISTER_TYPE,
CONF_RESPONSE_SIZE,
@ -114,6 +116,14 @@ ModbusCommandSentTrigger = modbus_controller_ns.class_(
"ModbusCommandSentTrigger", automation.Trigger.template(cg.int_, cg.int_)
)
ModbusOnlineTrigger = modbus_controller_ns.class_(
"ModbusOnlineTrigger", automation.Trigger.template(cg.int_, cg.int_)
)
ModbusOfflineTrigger = modbus_controller_ns.class_(
"ModbusOfflineTrigger", automation.Trigger.template(cg.int_, cg.int_)
)
_LOGGER = logging.getLogger(__name__)
ModbusServerRegisterSchema = cv.Schema(
@ -146,6 +156,16 @@ CONFIG_SCHEMA = cv.All(
),
}
),
cv.Optional(CONF_ON_ONLINE): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(ModbusOnlineTrigger),
}
),
cv.Optional(CONF_ON_OFFLINE): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(ModbusOnlineTrigger),
}
),
}
)
.extend(cv.polling_component_schema("60s"))
@ -284,7 +304,17 @@ async def to_code(config):
for conf in config.get(CONF_ON_COMMAND_SENT, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(
trigger, [(int, "function_code"), (int, "address")], conf
trigger, [(cg.int_, "function_code"), (cg.int_, "address")], conf
)
for conf in config.get(CONF_ON_ONLINE, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(
trigger, [(cg.int_, "function_code"), (cg.int_, "address")], conf
)
for conf in config.get(CONF_ON_OFFLINE, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(
trigger, [(cg.int_, "function_code"), (cg.int_, "address")], conf
)

View file

@ -15,5 +15,21 @@ class ModbusCommandSentTrigger : public Trigger<int, int> {
}
};
class ModbusOnlineTrigger : public Trigger<int, int> {
public:
ModbusOnlineTrigger(ModbusController *a_modbuscontroller) {
a_modbuscontroller->add_on_online_callback(
[this](int function_code, int address) { this->trigger(function_code, address); });
}
};
class ModbusOfflineTrigger : public Trigger<int, int> {
public:
ModbusOfflineTrigger(ModbusController *a_modbuscontroller) {
a_modbuscontroller->add_on_offline_callback(
[this](int function_code, int address) { this->trigger(function_code, address); });
}
};
} // namespace modbus_controller
} // namespace esphome

View file

@ -9,6 +9,8 @@ CONF_MAX_CMD_RETRIES = "max_cmd_retries"
CONF_MODBUS_CONTROLLER_ID = "modbus_controller_id"
CONF_MODBUS_FUNCTIONCODE = "modbus_functioncode"
CONF_ON_COMMAND_SENT = "on_command_sent"
CONF_ON_ONLINE = "on_online"
CONF_ON_OFFLINE = "on_offline"
CONF_RAW_ENCODE = "raw_encode"
CONF_REGISTER_COUNT = "register_count"
CONF_REGISTER_TYPE = "register_type"

View file

@ -32,8 +32,10 @@ bool ModbusController::send_next_command_() {
r.skip_updates_counter = this->offline_skip_updates_;
}
}
this->module_offline_ = true;
this->offline_callback_.call((int) command->function_code, command->register_address);
}
this->module_offline_ = true;
ESP_LOGD(TAG, "Modbus command to device=%d register=0x%02X no response received - removed from send queue",
this->address_, command->register_address);
this->command_queue_.pop_front();
@ -68,8 +70,10 @@ void ModbusController::on_modbus_data(const std::vector<uint8_t> &data) {
r.skip_updates_counter = 0;
}
}
// Restore module online state
this->module_offline_ = false;
this->online_callback_.call((int) current_command->function_code, current_command->register_address);
}
this->module_offline_ = false;
// Move the commandItem to the response queue
current_command->payload = data;
@ -670,5 +674,13 @@ void ModbusController::add_on_command_sent_callback(std::function<void(int, int)
this->command_sent_callback_.add(std::move(callback));
}
void ModbusController::add_on_online_callback(std::function<void(int, int)> &&callback) {
this->online_callback_.add(std::move(callback));
}
void ModbusController::add_on_offline_callback(std::function<void(int, int)> &&callback) {
this->offline_callback_.add(std::move(callback));
}
} // namespace modbus_controller
} // namespace esphome

View file

@ -468,6 +468,10 @@ class ModbusController : public PollingComponent, public modbus::ModbusDevice {
bool get_module_offline() { return module_offline_; }
/// Set callback for commands
void add_on_command_sent_callback(std::function<void(int, int)> &&callback);
/// Set callback for online changes
void add_on_online_callback(std::function<void(int, int)> &&callback);
/// Set callback for offline changes
void add_on_offline_callback(std::function<void(int, int)> &&callback);
/// called by esphome generated code to set the max_cmd_retries.
void set_max_cmd_retries(uint8_t max_cmd_retries) { this->max_cmd_retries_ = max_cmd_retries; }
/// get how many times a command will be (re)sent if no response is received
@ -508,7 +512,12 @@ class ModbusController : public PollingComponent, public modbus::ModbusDevice {
uint16_t offline_skip_updates_;
/// How many times we will retry a command if we get no response
uint8_t max_cmd_retries_{4};
/// Command sent callback
CallbackManager<void(int, int)> command_sent_callback_{};
/// Server online callback
CallbackManager<void(int, int)> online_callback_{};
/// Server offline callback
CallbackManager<void(int, int)> offline_callback_{};
};
/** Convert vector<uint8_t> response payload to float.

View file

@ -3,8 +3,9 @@ from typing import Any
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome import pins
from esphome.components import sensor
from esphome.const import CONF_ID, PLATFORM_ESP32, PLATFORM_ESP8266
from . import generate
from . import const, schema, validate, generate
CODEOWNERS = ["@olegtarasov"]
MULTI_CONF = True
@ -19,6 +20,7 @@ CONF_CH2_ACTIVE = "ch2_active"
CONF_SUMMER_MODE_ACTIVE = "summer_mode_active"
CONF_DHW_BLOCK = "dhw_block"
CONF_SYNC_MODE = "sync_mode"
CONF_OPENTHERM_VERSION = "opentherm_version"
CONFIG_SCHEMA = cv.All(
cv.Schema(
@ -34,8 +36,15 @@ CONFIG_SCHEMA = cv.All(
cv.Optional(CONF_SUMMER_MODE_ACTIVE, False): cv.boolean,
cv.Optional(CONF_DHW_BLOCK, False): cv.boolean,
cv.Optional(CONF_SYNC_MODE, False): cv.boolean,
cv.Optional(CONF_OPENTHERM_VERSION): cv.positive_float,
}
).extend(cv.COMPONENT_SCHEMA),
)
.extend(
validate.create_entities_schema(
schema.INPUTS, (lambda _: cv.use_id(sensor.Sensor))
)
)
.extend(cv.COMPONENT_SCHEMA),
cv.only_on([PLATFORM_ESP32, PLATFORM_ESP8266]),
)
@ -52,8 +61,23 @@ async def to_code(config: dict[str, Any]) -> None:
cg.add(var.set_out_pin(out_pin))
non_sensors = {CONF_ID, CONF_IN_PIN, CONF_OUT_PIN}
input_sensors = []
for key, value in config.items():
if key in non_sensors:
continue
if key in schema.INPUTS:
input_sensor = await cg.get_variable(value)
cg.add(
getattr(var, f"set_{key}_{const.INPUT_SENSOR.lower()}")(input_sensor)
)
input_sensors.append(key)
else:
cg.add(getattr(var, f"set_{key}")(value))
cg.add(getattr(var, f"set_{key}")(value))
if len(input_sensors) > 0:
generate.define_has_component(const.INPUT_SENSOR, input_sensors)
generate.define_message_handler(
const.INPUT_SENSOR, input_sensors, schema.INPUTS
)
generate.define_readers(const.INPUT_SENSOR, input_sensors)
generate.add_messages(var, input_sensors, schema.INPUTS)

View file

@ -0,0 +1,33 @@
from typing import Any
import esphome.config_validation as cv
from esphome.components import binary_sensor
from .. import const, schema, validate, generate
DEPENDENCIES = [const.OPENTHERM]
COMPONENT_TYPE = const.BINARY_SENSOR
def get_entity_validation_schema(entity: schema.BinarySensorSchema) -> cv.Schema:
return binary_sensor.binary_sensor_schema(
device_class=(
entity.device_class
or binary_sensor._UNDEF # pylint: disable=protected-access
),
icon=(entity.icon or binary_sensor._UNDEF), # pylint: disable=protected-access
)
CONFIG_SCHEMA = validate.create_component_schema(
schema.BINARY_SENSORS, get_entity_validation_schema
)
async def to_code(config: dict[str, Any]) -> None:
await generate.component_to_code(
COMPONENT_TYPE,
schema.BINARY_SENSORS,
binary_sensor.BinarySensor,
generate.create_only_conf(binary_sensor.new_binary_sensor),
config,
)

View file

@ -1,5 +1,11 @@
OPENTHERM = "opentherm"
CONF_OPENTHERM_ID = "opentherm_id"
CONF_DATA_TYPE = "data_type"
SENSOR = "sensor"
BINARY_SENSOR = "binary_sensor"
SWITCH = "switch"
NUMBER = "number"
OUTPUT = "output"
INPUT_SENSOR = "input_sensor"

View file

@ -130,6 +130,8 @@ async def component_to_code(
id = conf[CONF_ID]
if id and id.type == type:
entity = await create(conf, key, hub)
if const.CONF_DATA_TYPE in conf:
schemas[key].message_data = conf[const.CONF_DATA_TYPE]
cg.add(getattr(hub, f"set_{key}_{component_type.lower()}")(entity))
keys.append(key)

View file

@ -29,6 +29,8 @@ uint8_t parse_u8_hb(OpenthermData &data) { return data.valueHB; }
int8_t parse_s8_lb(OpenthermData &data) { return (int8_t) data.valueLB; }
int8_t parse_s8_hb(OpenthermData &data) { return (int8_t) data.valueHB; }
uint16_t parse_u16(OpenthermData &data) { return data.u16(); }
uint16_t parse_u8_lb_60(OpenthermData &data) { return data.valueLB * 60; }
uint16_t parse_u8_hb_60(OpenthermData &data) { return data.valueHB * 60; }
int16_t parse_s16(OpenthermData &data) { return data.s16(); }
float parse_f88(OpenthermData &data) { return data.f88(); }
@ -87,13 +89,40 @@ OpenthermData OpenthermHub::build_request_(MessageId request_id) const {
return data;
}
// Another special case is OpenTherm version number which is configured at hub level as a constant
if (request_id == MessageId::OT_VERSION_CONTROLLER) {
data.type = MessageType::WRITE_DATA;
data.id = MessageId::OT_VERSION_CONTROLLER;
data.f88(this->opentherm_version_);
return data;
}
// Disable incomplete switch statement warnings, because the cases in each
// switch are generated based on the configured sensors and inputs.
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wswitch"
switch (request_id) { OPENTHERM_SENSOR_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_READ_MESSAGE, OPENTHERM_IGNORE, , , ) }
// Next, we start with the write requests from switches and other inputs,
// because we would want to write that data if it is available, rather than
// request a read for that type (in the case that both read and write are
// supported).
switch (request_id) {
OPENTHERM_SWITCH_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_WRITE_MESSAGE, OPENTHERM_MESSAGE_WRITE_ENTITY, ,
OPENTHERM_MESSAGE_WRITE_POSTSCRIPT, )
OPENTHERM_NUMBER_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_WRITE_MESSAGE, OPENTHERM_MESSAGE_WRITE_ENTITY, ,
OPENTHERM_MESSAGE_WRITE_POSTSCRIPT, )
OPENTHERM_OUTPUT_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_WRITE_MESSAGE, OPENTHERM_MESSAGE_WRITE_ENTITY, ,
OPENTHERM_MESSAGE_WRITE_POSTSCRIPT, )
OPENTHERM_INPUT_SENSOR_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_WRITE_MESSAGE, OPENTHERM_MESSAGE_WRITE_ENTITY, ,
OPENTHERM_MESSAGE_WRITE_POSTSCRIPT, )
}
// Finally, handle the simple read requests, which only change with the message id.
switch (request_id) { OPENTHERM_SENSOR_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_READ_MESSAGE, OPENTHERM_IGNORE, , , ) }
switch (request_id) {
OPENTHERM_BINARY_SENSOR_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_READ_MESSAGE, OPENTHERM_IGNORE, , , )
}
#pragma GCC diagnostic pop
// And if we get here, a message was requested which somehow wasn't handled.
@ -115,6 +144,10 @@ void OpenthermHub::process_response(OpenthermData &data) {
OPENTHERM_SENSOR_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_RESPONSE_MESSAGE, OPENTHERM_MESSAGE_RESPONSE_ENTITY, ,
OPENTHERM_MESSAGE_RESPONSE_POSTSCRIPT, )
}
switch (data.id) {
OPENTHERM_BINARY_SENSOR_MESSAGE_HANDLERS(OPENTHERM_MESSAGE_RESPONSE_MESSAGE, OPENTHERM_MESSAGE_RESPONSE_ENTITY, ,
OPENTHERM_MESSAGE_RESPONSE_POSTSCRIPT, )
}
}
void OpenthermHub::setup() {
@ -131,6 +164,13 @@ void OpenthermHub::setup() {
// good practice anyway.
this->add_repeating_message(MessageId::STATUS);
// Also ensure that we start communication with the STATUS message
this->initial_messages_.insert(this->initial_messages_.begin(), MessageId::STATUS);
if (this->opentherm_version_ > 0.0f) {
this->initial_messages_.insert(this->initial_messages_.begin(), MessageId::OT_VERSION_CONTROLLER);
}
this->current_message_iterator_ = this->initial_messages_.begin();
}
@ -331,11 +371,11 @@ void OpenthermHub::dump_config() {
ESP_LOGCONFIG(TAG, " Numbers: %s", SHOW(OPENTHERM_NUMBER_LIST(ID, )));
ESP_LOGCONFIG(TAG, " Initial requests:");
for (auto type : this->initial_messages_) {
ESP_LOGCONFIG(TAG, " - %d", type);
ESP_LOGCONFIG(TAG, " - %d (%s)", type, this->opentherm_->message_id_to_str((type)));
}
ESP_LOGCONFIG(TAG, " Repeating requests:");
for (auto type : this->repeating_messages_) {
ESP_LOGCONFIG(TAG, " - %d", type);
ESP_LOGCONFIG(TAG, " - %d (%s)", type, this->opentherm_->message_id_to_str((type)));
}
}

View file

@ -4,6 +4,7 @@
#include "esphome/core/hal.h"
#include "esphome/core/component.h"
#include "esphome/core/log.h"
#include <vector>
#include "opentherm.h"
@ -11,6 +12,22 @@
#include "esphome/components/sensor/sensor.h"
#endif
#ifdef OPENTHERM_USE_BINARY_SENSOR
#include "esphome/components/binary_sensor/binary_sensor.h"
#endif
#ifdef OPENTHERM_USE_SWITCH
#include "esphome/components/opentherm/switch/switch.h"
#endif
#ifdef OPENTHERM_USE_OUTPUT
#include "esphome/components/opentherm/output/output.h"
#endif
#ifdef OPENTHERM_USE_NUMBER
#include "esphome/components/opentherm/number/number.h"
#endif
#include <memory>
#include <unordered_map>
#include <unordered_set>
@ -31,15 +48,25 @@ class OpenthermHub : public Component {
OPENTHERM_SENSOR_LIST(OPENTHERM_DECLARE_SENSOR, )
OPENTHERM_BINARY_SENSOR_LIST(OPENTHERM_DECLARE_BINARY_SENSOR, )
OPENTHERM_SWITCH_LIST(OPENTHERM_DECLARE_SWITCH, )
OPENTHERM_NUMBER_LIST(OPENTHERM_DECLARE_NUMBER, )
OPENTHERM_OUTPUT_LIST(OPENTHERM_DECLARE_OUTPUT, )
OPENTHERM_INPUT_SENSOR_LIST(OPENTHERM_DECLARE_INPUT_SENSOR, )
// The set of initial messages to send on starting communication with the boiler
std::unordered_set<MessageId> initial_messages_;
std::vector<MessageId> initial_messages_;
// and the repeating messages which are sent repeatedly to update various sensors
// and boiler parameters (like the setpoint).
std::unordered_set<MessageId> repeating_messages_;
std::vector<MessageId> repeating_messages_;
// Indicates if we are still working on the initial requests or not
bool sending_initial_ = true;
// Index for the current request in one of the _requests sets.
std::unordered_set<MessageId>::const_iterator current_message_iterator_;
std::vector<MessageId>::const_iterator current_message_iterator_;
uint32_t last_conversation_start_ = 0;
uint32_t last_conversation_end_ = 0;
@ -51,6 +78,8 @@ class OpenthermHub : public Component {
// Very likely to happen while using Dallas temperature sensors.
bool sync_mode_ = false;
float opentherm_version_ = 0.0f;
// Create OpenTherm messages based on the message id
OpenthermData build_request_(MessageId request_id) const;
void handle_protocol_write_error_();
@ -88,13 +117,23 @@ class OpenthermHub : public Component {
OPENTHERM_SENSOR_LIST(OPENTHERM_SET_SENSOR, )
// Add a request to the set of initial requests
void add_initial_message(MessageId message_id) { this->initial_messages_.insert(message_id); }
OPENTHERM_BINARY_SENSOR_LIST(OPENTHERM_SET_BINARY_SENSOR, )
OPENTHERM_SWITCH_LIST(OPENTHERM_SET_SWITCH, )
OPENTHERM_NUMBER_LIST(OPENTHERM_SET_NUMBER, )
OPENTHERM_OUTPUT_LIST(OPENTHERM_SET_OUTPUT, )
OPENTHERM_INPUT_SENSOR_LIST(OPENTHERM_SET_INPUT_SENSOR, )
// Add a request to the vector of initial requests
void add_initial_message(MessageId message_id) { this->initial_messages_.push_back(message_id); }
// Add a request to the set of repeating requests. Note that a large number of repeating
// requests will slow down communication with the boiler. Each request may take up to 1 second,
// so with all sensors enabled, it may take about half a minute before a change in setpoint
// will be processed.
void add_repeating_message(MessageId message_id) { this->repeating_messages_.insert(message_id); }
void add_repeating_message(MessageId message_id) { this->repeating_messages_.push_back(message_id); }
// There are seven status variables, which can either be set as a simple variable,
// or using a switch. ch_enable and dhw_enable default to true, the others to false.
@ -110,6 +149,7 @@ class OpenthermHub : public Component {
void set_summer_mode_active(bool value) { this->summer_mode_active = value; }
void set_dhw_block(bool value) { this->dhw_block = value; }
void set_sync_mode(bool sync_mode) { this->sync_mode_ = sync_mode; }
void set_opentherm_version(float value) { this->opentherm_version_ = value; }
float get_setup_priority() const override { return setup_priority::HARDWARE; }

View file

@ -0,0 +1,18 @@
#pragma once
namespace esphome {
namespace opentherm {
class OpenthermInput {
public:
bool auto_min_value, auto_max_value;
virtual void set_min_value(float min_value) = 0;
virtual void set_max_value(float max_value) = 0;
virtual void set_auto_min_value(bool auto_min_value) { this->auto_min_value = auto_min_value; }
virtual void set_auto_max_value(bool auto_max_value) { this->auto_max_value = auto_max_value; }
};
} // namespace opentherm
} // namespace esphome

View file

@ -0,0 +1,51 @@
from typing import Any
import esphome.codegen as cg
import esphome.config_validation as cv
from . import schema, generate
CONF_min_value = "min_value"
CONF_max_value = "max_value"
CONF_auto_min_value = "auto_min_value"
CONF_auto_max_value = "auto_max_value"
CONF_step = "step"
OpenthermInput = generate.opentherm_ns.class_("OpenthermInput")
def validate_min_value_less_than_max_value(conf):
if (
CONF_min_value in conf
and CONF_max_value in conf
and conf[CONF_min_value] > conf[CONF_max_value]
):
raise cv.Invalid(f"{CONF_min_value} must be less than {CONF_max_value}")
return conf
def input_schema(entity: schema.InputSchema) -> cv.Schema:
result = cv.Schema(
{
cv.Optional(CONF_min_value, entity.range[0]): cv.float_range(
entity.range[0], entity.range[1]
),
cv.Optional(CONF_max_value, entity.range[1]): cv.float_range(
entity.range[0], entity.range[1]
),
}
)
result = result.add_extra(validate_min_value_less_than_max_value)
result = result.extend({cv.Optional(CONF_step, False): cv.float_})
if entity.auto_min_value is not None:
result = result.extend({cv.Optional(CONF_auto_min_value, False): cv.boolean})
if entity.auto_max_value is not None:
result = result.extend({cv.Optional(CONF_auto_max_value, False): cv.boolean})
return result
def generate_setters(entity: cg.MockObj, conf: dict[str, Any]) -> None:
generate.add_property_set(entity, CONF_min_value, conf)
generate.add_property_set(entity, CONF_max_value, conf)
generate.add_property_set(entity, CONF_auto_min_value, conf)
generate.add_property_set(entity, CONF_auto_max_value, conf)

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@ -0,0 +1,74 @@
from typing import Any
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import number
from esphome.const import (
CONF_ID,
CONF_UNIT_OF_MEASUREMENT,
CONF_STEP,
CONF_INITIAL_VALUE,
CONF_RESTORE_VALUE,
)
from .. import const, schema, validate, input, generate
DEPENDENCIES = [const.OPENTHERM]
COMPONENT_TYPE = const.NUMBER
OpenthermNumber = generate.opentherm_ns.class_(
"OpenthermNumber", number.Number, cg.Component, input.OpenthermInput
)
async def new_openthermnumber(config: dict[str, Any]) -> cg.Pvariable:
var = cg.new_Pvariable(config[CONF_ID])
await cg.register_component(var, config)
await number.register_number(
var,
config,
min_value=config[input.CONF_min_value],
max_value=config[input.CONF_max_value],
step=config[input.CONF_step],
)
input.generate_setters(var, config)
if CONF_INITIAL_VALUE in config:
cg.add(var.set_initial_value(config[CONF_INITIAL_VALUE]))
if CONF_RESTORE_VALUE in config:
cg.add(var.set_restore_value(config[CONF_RESTORE_VALUE]))
return var
def get_entity_validation_schema(entity: schema.InputSchema) -> cv.Schema:
return (
number.NUMBER_SCHEMA.extend(
{
cv.GenerateID(): cv.declare_id(OpenthermNumber),
cv.Optional(
CONF_UNIT_OF_MEASUREMENT, entity.unit_of_measurement
): cv.string_strict,
cv.Optional(CONF_STEP, entity.step): cv.float_,
cv.Optional(CONF_INITIAL_VALUE): cv.float_,
cv.Optional(CONF_RESTORE_VALUE): cv.boolean,
}
)
.extend(input.input_schema(entity))
.extend(cv.COMPONENT_SCHEMA)
)
CONFIG_SCHEMA = validate.create_component_schema(
schema.INPUTS, get_entity_validation_schema
)
async def to_code(config: dict[str, Any]) -> None:
keys = await generate.component_to_code(
COMPONENT_TYPE,
schema.INPUTS,
OpenthermNumber,
generate.create_only_conf(new_openthermnumber),
config,
)
generate.define_readers(COMPONENT_TYPE, keys)

View file

@ -0,0 +1,40 @@
#include "number.h"
namespace esphome {
namespace opentherm {
static const char *const TAG = "opentherm.number";
void OpenthermNumber::control(float value) {
this->publish_state(value);
if (this->restore_value_)
this->pref_.save(&value);
}
void OpenthermNumber::setup() {
float value;
if (!this->restore_value_) {
value = this->initial_value_;
} else {
this->pref_ = global_preferences->make_preference<float>(this->get_object_id_hash());
if (!this->pref_.load(&value)) {
if (!std::isnan(this->initial_value_)) {
value = this->initial_value_;
} else {
value = this->traits.get_min_value();
}
}
}
this->publish_state(value);
}
void OpenthermNumber::dump_config() {
LOG_NUMBER("", "OpenTherm Number", this);
ESP_LOGCONFIG(TAG, " Restore value: %d", this->restore_value_);
ESP_LOGCONFIG(TAG, " Initial value: %.2f", this->initial_value_);
ESP_LOGCONFIG(TAG, " Current value: %.2f", this->state);
}
} // namespace opentherm
} // namespace esphome

View file

@ -0,0 +1,31 @@
#pragma once
#include "esphome/components/number/number.h"
#include "esphome/core/preferences.h"
#include "esphome/core/log.h"
#include "esphome/components/opentherm/input.h"
namespace esphome {
namespace opentherm {
// Just a simple number, which stores the number
class OpenthermNumber : public number::Number, public Component, public OpenthermInput {
protected:
void control(float value) override;
void setup() override;
void dump_config() override;
float initial_value_{NAN};
bool restore_value_{false};
ESPPreferenceObject pref_;
public:
void set_min_value(float min_value) override { this->traits.set_min_value(min_value); }
void set_max_value(float max_value) override { this->traits.set_max_value(max_value); }
void set_initial_value(float initial_value) { initial_value_ = initial_value; }
void set_restore_value(bool restore_value) { this->restore_value_ = restore_value; }
};
} // namespace opentherm
} // namespace esphome

View file

@ -483,6 +483,8 @@ const char *OpenTherm::message_id_to_str(MessageId id) {
TO_STRING_MEMBER(EXHAUST_TEMP)
TO_STRING_MEMBER(FAN_SPEED)
TO_STRING_MEMBER(FLAME_CURRENT)
TO_STRING_MEMBER(ROOM_TEMP_CH2)
TO_STRING_MEMBER(REL_HUMIDITY)
TO_STRING_MEMBER(DHW_BOUNDS)
TO_STRING_MEMBER(CH_BOUNDS)
TO_STRING_MEMBER(OTC_CURVE_BOUNDS)
@ -492,14 +494,39 @@ const char *OpenTherm::message_id_to_str(MessageId id) {
TO_STRING_MEMBER(HVAC_STATUS)
TO_STRING_MEMBER(REL_VENT_SETPOINT)
TO_STRING_MEMBER(DEVICE_VENT)
TO_STRING_MEMBER(HVAC_VER_ID)
TO_STRING_MEMBER(REL_VENTILATION)
TO_STRING_MEMBER(REL_HUMID_EXHAUST)
TO_STRING_MEMBER(EXHAUST_CO2)
TO_STRING_MEMBER(SUPPLY_INLET_TEMP)
TO_STRING_MEMBER(SUPPLY_OUTLET_TEMP)
TO_STRING_MEMBER(EXHAUST_INLET_TEMP)
TO_STRING_MEMBER(EXHAUST_OUTLET_TEMP)
TO_STRING_MEMBER(EXHAUST_FAN_SPEED)
TO_STRING_MEMBER(SUPPLY_FAN_SPEED)
TO_STRING_MEMBER(REMOTE_VENTILATION_PARAM)
TO_STRING_MEMBER(NOM_REL_VENTILATION)
TO_STRING_MEMBER(HVAC_NUM_TSP)
TO_STRING_MEMBER(HVAC_IDX_TSP)
TO_STRING_MEMBER(HVAC_FHB_SIZE)
TO_STRING_MEMBER(HVAC_FHB_IDX)
TO_STRING_MEMBER(RF_SIGNAL)
TO_STRING_MEMBER(DHW_MODE)
TO_STRING_MEMBER(OVERRIDE_FUNC)
TO_STRING_MEMBER(SOLAR_MODE_FLAGS)
TO_STRING_MEMBER(SOLAR_ASF)
TO_STRING_MEMBER(SOLAR_VERSION_ID)
TO_STRING_MEMBER(SOLAR_PRODUCT_ID)
TO_STRING_MEMBER(SOLAR_NUM_TSP)
TO_STRING_MEMBER(SOLAR_IDX_TSP)
TO_STRING_MEMBER(SOLAR_FHB_SIZE)
TO_STRING_MEMBER(SOLAR_FHB_IDX)
TO_STRING_MEMBER(SOLAR_STARTS)
TO_STRING_MEMBER(SOLAR_HOURS)
TO_STRING_MEMBER(SOLAR_ENERGY)
TO_STRING_MEMBER(SOLAR_TOTAL_ENERGY)
TO_STRING_MEMBER(FAILED_BURNER_STARTS)
TO_STRING_MEMBER(BURNER_FLAME_LOW)
TO_STRING_MEMBER(OEM_DIAGNOSTIC)
TO_STRING_MEMBER(BURNER_STARTS)
TO_STRING_MEMBER(CH_PUMP_STARTS)

View file

@ -99,6 +99,8 @@ enum MessageId {
EXHAUST_TEMP = 33,
FAN_SPEED = 35,
FLAME_CURRENT = 36,
ROOM_TEMP_CH2 = 37,
REL_HUMIDITY = 38,
DHW_BOUNDS = 48,
CH_BOUNDS = 49,
OTC_CURVE_BOUNDS = 50,
@ -110,15 +112,46 @@ enum MessageId {
HVAC_STATUS = 70,
REL_VENT_SETPOINT = 71,
DEVICE_VENT = 74,
HVAC_VER_ID = 75,
REL_VENTILATION = 77,
REL_HUMID_EXHAUST = 78,
EXHAUST_CO2 = 79,
SUPPLY_INLET_TEMP = 80,
SUPPLY_OUTLET_TEMP = 81,
EXHAUST_INLET_TEMP = 82,
EXHAUST_OUTLET_TEMP = 83,
EXHAUST_FAN_SPEED = 84,
SUPPLY_FAN_SPEED = 85,
REMOTE_VENTILATION_PARAM = 86,
NOM_REL_VENTILATION = 87,
HVAC_NUM_TSP = 88,
HVAC_IDX_TSP = 89,
HVAC_FHB_SIZE = 90,
HVAC_FHB_IDX = 91,
RF_SIGNAL = 98,
DHW_MODE = 99,
OVERRIDE_FUNC = 100,
// Solar Specific Message IDs
SOLAR_MODE_FLAGS = 101, // hb0-2 Controller storage mode
// lb0 Device fault
// lb1-3 Device mode status
// lb4-5 Device status
SOLAR_ASF = 102,
SOLAR_VERSION_ID = 103,
SOLAR_PRODUCT_ID = 104,
SOLAR_NUM_TSP = 105,
SOLAR_IDX_TSP = 106,
SOLAR_FHB_SIZE = 107,
SOLAR_FHB_IDX = 108,
SOLAR_STARTS = 109,
SOLAR_HOURS = 110,
SOLAR_ENERGY = 111,
SOLAR_TOTAL_ENERGY = 112,
FAILED_BURNER_STARTS = 113,
BURNER_FLAME_LOW = 114,
OEM_DIAGNOSTIC = 115,
BURNER_STARTS = 116,
CH_PUMP_STARTS = 117,

View file

@ -13,14 +13,49 @@ namespace opentherm {
#ifndef OPENTHERM_SENSOR_LIST
#define OPENTHERM_SENSOR_LIST(F, sep)
#endif
#ifndef OPENTHERM_BINARY_SENSOR_LIST
#define OPENTHERM_BINARY_SENSOR_LIST(F, sep)
#endif
#ifndef OPENTHERM_SWITCH_LIST
#define OPENTHERM_SWITCH_LIST(F, sep)
#endif
#ifndef OPENTHERM_NUMBER_LIST
#define OPENTHERM_NUMBER_LIST(F, sep)
#endif
#ifndef OPENTHERM_OUTPUT_LIST
#define OPENTHERM_OUTPUT_LIST(F, sep)
#endif
#ifndef OPENTHERM_INPUT_SENSOR_LIST
#define OPENTHERM_INPUT_SENSOR_LIST(F, sep)
#endif
// Use macros to create fields for every entity specified in the ESPHome configuration
#define OPENTHERM_DECLARE_SENSOR(entity) sensor::Sensor *entity;
#define OPENTHERM_DECLARE_BINARY_SENSOR(entity) binary_sensor::BinarySensor *entity;
#define OPENTHERM_DECLARE_SWITCH(entity) OpenthermSwitch *entity;
#define OPENTHERM_DECLARE_NUMBER(entity) OpenthermNumber *entity;
#define OPENTHERM_DECLARE_OUTPUT(entity) OpenthermOutput *entity;
#define OPENTHERM_DECLARE_INPUT_SENSOR(entity) sensor::Sensor *entity;
// Setter macros
#define OPENTHERM_SET_SENSOR(entity) \
void set_##entity(sensor::Sensor *sensor) { this->entity = sensor; }
#define OPENTHERM_SET_BINARY_SENSOR(entity) \
void set_##entity(binary_sensor::BinarySensor *binary_sensor) { this->entity = binary_sensor; }
#define OPENTHERM_SET_SWITCH(entity) \
void set_##entity(OpenthermSwitch *sw) { this->entity = sw; }
#define OPENTHERM_SET_NUMBER(entity) \
void set_##entity(OpenthermNumber *number) { this->entity = number; }
#define OPENTHERM_SET_OUTPUT(entity) \
void set_##entity(OpenthermOutput *output) { this->entity = output; }
#define OPENTHERM_SET_INPUT_SENSOR(entity) \
void set_##entity(sensor::Sensor *sensor) { this->entity = sensor; }
// ===== hub.cpp macros =====
// *_MESSAGE_HANDLERS are generated in defines.h and look like this:
@ -35,6 +70,31 @@ namespace opentherm {
#ifndef OPENTHERM_SENSOR_MESSAGE_HANDLERS
#define OPENTHERM_SENSOR_MESSAGE_HANDLERS(MESSAGE, ENTITY, entity_sep, postscript, msg_sep)
#endif
#ifndef OPENTHERM_BINARY_SENSOR_MESSAGE_HANDLERS
#define OPENTHERM_BINARY_SENSOR_MESSAGE_HANDLERS(MESSAGE, ENTITY, entity_sep, postscript, msg_sep)
#endif
#ifndef OPENTHERM_SWITCH_MESSAGE_HANDLERS
#define OPENTHERM_SWITCH_MESSAGE_HANDLERS(MESSAGE, ENTITY, entity_sep, postscript, msg_sep)
#endif
#ifndef OPENTHERM_NUMBER_MESSAGE_HANDLERS
#define OPENTHERM_NUMBER_MESSAGE_HANDLERS(MESSAGE, ENTITY, entity_sep, postscript, msg_sep)
#endif
#ifndef OPENTHERM_OUTPUT_MESSAGE_HANDLERS
#define OPENTHERM_OUTPUT_MESSAGE_HANDLERS(MESSAGE, ENTITY, entity_sep, postscript, msg_sep)
#endif
#ifndef OPENTHERM_INPUT_SENSOR_MESSAGE_HANDLERS
#define OPENTHERM_INPUT_SENSOR_MESSAGE_HANDLERS(MESSAGE, ENTITY, entity_sep, postscript, msg_sep)
#endif
// Write data request builders
#define OPENTHERM_MESSAGE_WRITE_MESSAGE(msg) \
case MessageId::msg: { \
data.type = MessageType::WRITE_DATA; \
data.id = request_id;
#define OPENTHERM_MESSAGE_WRITE_ENTITY(key, msg_data) message_data::write_##msg_data(this->key->state, data);
#define OPENTHERM_MESSAGE_WRITE_POSTSCRIPT \
return data; \
}
// Read data request builder
#define OPENTHERM_MESSAGE_READ_MESSAGE(msg) \

View file

@ -0,0 +1,47 @@
from typing import Any
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import output
from esphome.const import CONF_ID
from .. import const, schema, validate, input, generate
DEPENDENCIES = [const.OPENTHERM]
COMPONENT_TYPE = const.OUTPUT
OpenthermOutput = generate.opentherm_ns.class_(
"OpenthermOutput", output.FloatOutput, cg.Component, input.OpenthermInput
)
async def new_openthermoutput(
config: dict[str, Any], key: str, _hub: cg.MockObj
) -> cg.Pvariable:
var = cg.new_Pvariable(config[CONF_ID])
await cg.register_component(var, config)
await output.register_output(var, config)
cg.add(getattr(var, "set_id")(cg.RawExpression(f'"{key}_{config[CONF_ID]}"')))
input.generate_setters(var, config)
return var
def get_entity_validation_schema(entity: schema.InputSchema) -> cv.Schema:
return (
output.FLOAT_OUTPUT_SCHEMA.extend(
{cv.GenerateID(): cv.declare_id(OpenthermOutput)}
)
.extend(input.input_schema(entity))
.extend(cv.COMPONENT_SCHEMA)
)
CONFIG_SCHEMA = validate.create_component_schema(
schema.INPUTS, get_entity_validation_schema
)
async def to_code(config: dict[str, Any]) -> None:
keys = await generate.component_to_code(
COMPONENT_TYPE, schema.INPUTS, OpenthermOutput, new_openthermoutput, config
)
generate.define_readers(COMPONENT_TYPE, keys)

View file

@ -0,0 +1,18 @@
#include "esphome/core/helpers.h" // for clamp() and lerp()
#include "output.h"
namespace esphome {
namespace opentherm {
static const char *const TAG = "opentherm.output";
void opentherm::OpenthermOutput::write_state(float state) {
ESP_LOGD(TAG, "Received state: %.2f. Min value: %.2f, max value: %.2f", state, min_value_, max_value_);
this->state = state < 0.003 && this->zero_means_zero_
? 0.0
: clamp(lerp(state, min_value_, max_value_), min_value_, max_value_);
this->has_state_ = true;
ESP_LOGD(TAG, "Output %s set to %.2f", this->id_, this->state);
}
} // namespace opentherm
} // namespace esphome

View file

@ -0,0 +1,33 @@
#pragma once
#include "esphome/components/output/float_output.h"
#include "esphome/components/opentherm/input.h"
#include "esphome/core/log.h"
namespace esphome {
namespace opentherm {
class OpenthermOutput : public output::FloatOutput, public Component, public OpenthermInput {
protected:
bool has_state_ = false;
const char *id_ = nullptr;
float min_value_, max_value_;
public:
float state;
void set_id(const char *id) { this->id_ = id; }
void write_state(float state) override;
bool has_state() { return this->has_state_; };
void set_min_value(float min_value) override { this->min_value_ = min_value; }
void set_max_value(float max_value) override { this->max_value_ = max_value; }
float get_min_value() { return this->min_value_; }
float get_max_value() { return this->max_value_; }
};
} // namespace opentherm
} // namespace esphome

View file

@ -11,9 +11,12 @@ from esphome.const import (
UNIT_MICROAMP,
UNIT_PERCENT,
UNIT_REVOLUTIONS_PER_MINUTE,
DEVICE_CLASS_COLD,
DEVICE_CLASS_CURRENT,
DEVICE_CLASS_EMPTY,
DEVICE_CLASS_HEAT,
DEVICE_CLASS_PRESSURE,
DEVICE_CLASS_PROBLEM,
DEVICE_CLASS_TEMPERATURE,
STATE_CLASS_MEASUREMENT,
STATE_CLASS_NONE,
@ -188,11 +191,23 @@ SENSORS: dict[str, SensorSchema] = {
description="Boiler fan speed",
unit_of_measurement=UNIT_REVOLUTIONS_PER_MINUTE,
accuracy_decimals=0,
icon="mdi:fan",
device_class=DEVICE_CLASS_EMPTY,
state_class=STATE_CLASS_MEASUREMENT,
message="FAN_SPEED",
keep_updated=True,
message_data="u16",
message_data="u8_lb_60",
),
"fan_speed_setpoint": SensorSchema(
description="Boiler fan speed setpoint",
unit_of_measurement=UNIT_REVOLUTIONS_PER_MINUTE,
accuracy_decimals=0,
icon="mdi:fan",
device_class=DEVICE_CLASS_EMPTY,
state_class=STATE_CLASS_MEASUREMENT,
message="FAN_SPEED",
keep_updated=True,
message_data="u8_hb_60",
),
"flame_current": SensorSchema(
description="Boiler flame current",
@ -436,3 +451,364 @@ SENSORS: dict[str, SensorSchema] = {
message_data="u8_lb",
),
}
@dataclass
class BinarySensorSchema(EntitySchema):
icon: Optional[str] = None
device_class: Optional[str] = None
BINARY_SENSORS: dict[str, BinarySensorSchema] = {
"fault_indication": BinarySensorSchema(
description="Status: Fault indication",
device_class=DEVICE_CLASS_PROBLEM,
message="STATUS",
keep_updated=True,
message_data="flag8_lb_0",
),
"ch_active": BinarySensorSchema(
description="Status: Central Heating active",
device_class=DEVICE_CLASS_HEAT,
icon="mdi:radiator",
message="STATUS",
keep_updated=True,
message_data="flag8_lb_1",
),
"dhw_active": BinarySensorSchema(
description="Status: Domestic Hot Water active",
device_class=DEVICE_CLASS_HEAT,
icon="mdi:faucet",
message="STATUS",
keep_updated=True,
message_data="flag8_lb_2",
),
"flame_on": BinarySensorSchema(
description="Status: Flame on",
device_class=DEVICE_CLASS_HEAT,
icon="mdi:fire",
message="STATUS",
keep_updated=True,
message_data="flag8_lb_3",
),
"cooling_active": BinarySensorSchema(
description="Status: Cooling active",
device_class=DEVICE_CLASS_COLD,
message="STATUS",
keep_updated=True,
message_data="flag8_lb_4",
),
"ch2_active": BinarySensorSchema(
description="Status: Central Heating 2 active",
device_class=DEVICE_CLASS_HEAT,
icon="mdi:radiator",
message="STATUS",
keep_updated=True,
message_data="flag8_lb_5",
),
"diagnostic_indication": BinarySensorSchema(
description="Status: Diagnostic event",
device_class=DEVICE_CLASS_PROBLEM,
message="STATUS",
keep_updated=True,
message_data="flag8_lb_6",
),
"electricity_production": BinarySensorSchema(
description="Status: Electricity production",
device_class=DEVICE_CLASS_PROBLEM,
message="STATUS",
keep_updated=True,
message_data="flag8_lb_7",
),
"dhw_present": BinarySensorSchema(
description="Configuration: DHW present",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_0",
),
"control_type_on_off": BinarySensorSchema(
description="Configuration: Control type is on/off",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_1",
),
"cooling_supported": BinarySensorSchema(
description="Configuration: Cooling supported",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_2",
),
"dhw_storage_tank": BinarySensorSchema(
description="Configuration: DHW storage tank",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_3",
),
"controller_pump_control_allowed": BinarySensorSchema(
description="Configuration: Controller pump control allowed",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_4",
),
"ch2_present": BinarySensorSchema(
description="Configuration: CH2 present",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_5",
),
"water_filling": BinarySensorSchema(
description="Configuration: Remote water filling",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_6",
),
"heat_mode": BinarySensorSchema(
description="Configuration: Heating or cooling",
message="DEVICE_CONFIG",
keep_updated=False,
message_data="flag8_hb_7",
),
"dhw_setpoint_transfer_enabled": BinarySensorSchema(
description="Remote boiler parameters: DHW setpoint transfer enabled",
message="REMOTE",
keep_updated=False,
message_data="flag8_hb_0",
),
"max_ch_setpoint_transfer_enabled": BinarySensorSchema(
description="Remote boiler parameters: CH maximum setpoint transfer enabled",
message="REMOTE",
keep_updated=False,
message_data="flag8_hb_1",
),
"dhw_setpoint_rw": BinarySensorSchema(
description="Remote boiler parameters: DHW setpoint read/write",
message="REMOTE",
keep_updated=False,
message_data="flag8_lb_0",
),
"max_ch_setpoint_rw": BinarySensorSchema(
description="Remote boiler parameters: CH maximum setpoint read/write",
message="REMOTE",
keep_updated=False,
message_data="flag8_lb_1",
),
"service_request": BinarySensorSchema(
description="Service required",
device_class=DEVICE_CLASS_PROBLEM,
message="FAULT_FLAGS",
keep_updated=True,
message_data="flag8_hb_0",
),
"lockout_reset": BinarySensorSchema(
description="Lockout Reset",
device_class=DEVICE_CLASS_PROBLEM,
message="FAULT_FLAGS",
keep_updated=True,
message_data="flag8_hb_1",
),
"low_water_pressure": BinarySensorSchema(
description="Low water pressure fault",
device_class=DEVICE_CLASS_PROBLEM,
message="FAULT_FLAGS",
keep_updated=True,
message_data="flag8_hb_2",
),
"flame_fault": BinarySensorSchema(
description="Flame fault",
device_class=DEVICE_CLASS_PROBLEM,
message="FAULT_FLAGS",
keep_updated=True,
message_data="flag8_hb_3",
),
"air_pressure_fault": BinarySensorSchema(
description="Air pressure fault",
device_class=DEVICE_CLASS_PROBLEM,
message="FAULT_FLAGS",
keep_updated=True,
message_data="flag8_hb_4",
),
"water_over_temp": BinarySensorSchema(
description="Water overtemperature",
device_class=DEVICE_CLASS_PROBLEM,
message="FAULT_FLAGS",
keep_updated=True,
message_data="flag8_hb_5",
),
}
@dataclass
class SwitchSchema(EntitySchema):
default_mode: Optional[str] = None
SWITCHES: dict[str, SwitchSchema] = {
"ch_enable": SwitchSchema(
description="Central Heating enabled",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_0",
default_mode="restore_default_off",
),
"dhw_enable": SwitchSchema(
description="Domestic Hot Water enabled",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_1",
default_mode="restore_default_off",
),
"cooling_enable": SwitchSchema(
description="Cooling enabled",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_2",
default_mode="restore_default_off",
),
"otc_active": SwitchSchema(
description="Outside temperature compensation active",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_3",
default_mode="restore_default_off",
),
"ch2_active": SwitchSchema(
description="Central Heating 2 active",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_4",
default_mode="restore_default_off",
),
"summer_mode_active": SwitchSchema(
description="Summer mode active",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_5",
default_mode="restore_default_off",
),
"dhw_block": SwitchSchema(
description="DHW blocked",
message="STATUS",
keep_updated=True,
message_data="flag8_hb_6",
default_mode="restore_default_off",
),
}
@dataclass
class AutoConfigure:
message: str
message_data: str
@dataclass
class InputSchema(EntitySchema):
unit_of_measurement: str
step: float
range: tuple[int, int]
icon: Optional[str] = None
auto_max_value: Optional[AutoConfigure] = None
auto_min_value: Optional[AutoConfigure] = None
INPUTS: dict[str, InputSchema] = {
"t_set": InputSchema(
description="Control setpoint: temperature setpoint for the boiler's supply water",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="CH_SETPOINT",
keep_updated=True,
message_data="f88",
range=(0, 100),
auto_max_value=AutoConfigure(message="MAX_CH_SETPOINT", message_data="f88"),
),
"t_set_ch2": InputSchema(
description="Control setpoint 2: temperature setpoint for the boiler's supply water on the second heating circuit",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="CH2_SETPOINT",
keep_updated=True,
message_data="f88",
range=(0, 100),
auto_max_value=AutoConfigure(message="MAX_CH_SETPOINT", message_data="f88"),
),
"cooling_control": InputSchema(
description="Cooling control signal",
unit_of_measurement=UNIT_PERCENT,
step=1.0,
message="COOLING_CONTROL",
keep_updated=True,
message_data="f88",
range=(0, 100),
),
"t_dhw_set": InputSchema(
description="Domestic hot water temperature setpoint",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="DHW_SETPOINT",
keep_updated=True,
message_data="f88",
range=(0, 127),
auto_min_value=AutoConfigure(message="DHW_BOUNDS", message_data="s8_lb"),
auto_max_value=AutoConfigure(message="DHW_BOUNDS", message_data="s8_hb"),
),
"max_t_set": InputSchema(
description="Maximum allowable CH water setpoint",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="MAX_CH_SETPOINT",
keep_updated=True,
message_data="f88",
range=(0, 127),
auto_min_value=AutoConfigure(message="CH_BOUNDS", message_data="s8_lb"),
auto_max_value=AutoConfigure(message="CH_BOUNDS", message_data="s8_hb"),
),
"t_room_set": InputSchema(
description="Current room temperature setpoint (informational)",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="ROOM_SETPOINT",
keep_updated=True,
message_data="f88",
range=(-40, 127),
),
"t_room_set_ch2": InputSchema(
description="Current room temperature setpoint on CH2 (informational)",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="ROOM_SETPOINT_CH2",
keep_updated=True,
message_data="f88",
range=(-40, 127),
),
"t_room": InputSchema(
description="Current sensed room temperature (informational)",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="ROOM_TEMP",
keep_updated=True,
message_data="f88",
range=(-40, 127),
),
"max_rel_mod_level": InputSchema(
description="Maximum relative modulation level",
unit_of_measurement=UNIT_PERCENT,
step=1,
icon="mdi:percent",
message="MAX_MODULATION_LEVEL",
keep_updated=True,
message_data="f88",
range=(0, 100),
),
"otc_hc_ratio": InputSchema(
description="OTC heat curve ratio",
unit_of_measurement=UNIT_CELSIUS,
step=0.1,
message="OTC_CURVE_RATIO",
keep_updated=True,
message_data="f88",
range=(0, 127),
auto_min_value=AutoConfigure(message="OTC_CURVE_BOUNDS", message_data="u8_lb"),
auto_max_value=AutoConfigure(message="OTC_CURVE_BOUNDS", message_data="u8_hb"),
),
}

View file

@ -7,6 +7,18 @@ from .. import const, schema, validate, generate
DEPENDENCIES = [const.OPENTHERM]
COMPONENT_TYPE = const.SENSOR
MSG_DATA_TYPES = {
"u8_lb",
"u8_hb",
"s8_lb",
"s8_hb",
"u8_lb_60",
"u8_hb_60",
"u16",
"s16",
"f88",
}
def get_entity_validation_schema(entity: schema.SensorSchema) -> cv.Schema:
return sensor.sensor_schema(
@ -17,6 +29,10 @@ def get_entity_validation_schema(entity: schema.SensorSchema) -> cv.Schema:
or sensor._UNDEF, # pylint: disable=protected-access
icon=entity.icon or sensor._UNDEF, # pylint: disable=protected-access
state_class=entity.state_class,
).extend(
{
cv.Optional(const.CONF_DATA_TYPE): cv.one_of(*MSG_DATA_TYPES),
}
)

View file

@ -0,0 +1,43 @@
from typing import Any
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import switch
from esphome.const import CONF_ID
from .. import const, schema, validate, generate
DEPENDENCIES = [const.OPENTHERM]
COMPONENT_TYPE = const.SWITCH
OpenthermSwitch = generate.opentherm_ns.class_(
"OpenthermSwitch", switch.Switch, cg.Component
)
async def new_openthermswitch(config: dict[str, Any]) -> cg.Pvariable:
var = cg.new_Pvariable(config[CONF_ID])
await cg.register_component(var, config)
await switch.register_switch(var, config)
return var
def get_entity_validation_schema(entity: schema.SwitchSchema) -> cv.Schema:
return switch.SWITCH_SCHEMA.extend(
{cv.GenerateID(): cv.declare_id(OpenthermSwitch)}
).extend(cv.COMPONENT_SCHEMA)
CONFIG_SCHEMA = validate.create_component_schema(
schema.SWITCHES, get_entity_validation_schema
)
async def to_code(config: dict[str, Any]) -> None:
keys = await generate.component_to_code(
COMPONENT_TYPE,
schema.SWITCHES,
OpenthermSwitch,
generate.create_only_conf(new_openthermswitch),
config,
)
generate.define_readers(COMPONENT_TYPE, keys)

View file

@ -0,0 +1,28 @@
#include "switch.h"
namespace esphome {
namespace opentherm {
static const char *const TAG = "opentherm.switch";
void OpenthermSwitch::write_state(bool state) { this->publish_state(state); }
void OpenthermSwitch::setup() {
auto restored = this->get_initial_state_with_restore_mode();
bool state = false;
if (!restored.has_value()) {
ESP_LOGD(TAG, "Couldn't restore state for OpenTherm switch '%s'", this->get_name().c_str());
} else {
ESP_LOGD(TAG, "Restored state for OpenTherm switch '%s': %d", this->get_name().c_str(), restored.value());
state = restored.value();
}
this->write_state(state);
}
void OpenthermSwitch::dump_config() {
LOG_SWITCH("", "OpenTherm Switch", this);
ESP_LOGCONFIG(TAG, " Current state: %d", this->state);
}
} // namespace opentherm
} // namespace esphome

View file

@ -0,0 +1,20 @@
#pragma once
#include "esphome/core/component.h"
#include "esphome/components/switch/switch.h"
#include "esphome/core/log.h"
namespace esphome {
namespace opentherm {
class OpenthermSwitch : public switch_::Switch, public Component {
protected:
void write_state(bool state) override;
public:
void setup() override;
void dump_config() override;
};
} // namespace opentherm
} // namespace esphome

View file

@ -38,7 +38,7 @@ void SDMMeter::on_modbus_data(const std::vector<uint8_t> &data) {
ESP_LOGD(
TAG,
"SDMMeter Phase %c: V=%.3f V, I=%.3f A, Active P=%.3f W, Apparent P=%.3f VA, Reactive P=%.3f VAR, PF=%.3f, "
"SDMMeter Phase %c: V=%.3f V, I=%.3f A, Active P=%.3f W, Apparent P=%.3f VA, Reactive P=%.3f var, PF=%.3f, "
"PA=%.3f °",
i + 'A', voltage, current, active_power, apparent_power, reactive_power, power_factor, phase_angle);
if (phase.voltage_sensor_ != nullptr)

View file

@ -59,6 +59,9 @@ class Sun {
void set_latitude(double latitude) { location_.latitude = latitude; }
void set_longitude(double longitude) { location_.longitude = longitude; }
// Check if the sun is above the horizon, with a default elevation angle of -0.83333 (standard for sunrise/set).
bool is_above_horizon(double elevation = -0.83333) { return this->elevation() > elevation; }
optional<ESPTime> sunrise(double elevation);
optional<ESPTime> sunset(double elevation);
optional<ESPTime> sunrise(ESPTime date, double elevation);

View file

@ -1,6 +1,6 @@
"""Constants used by esphome."""
__version__ = "2024.11.0-dev"
__version__ = "2024.12.0-dev"
ALLOWED_NAME_CHARS = "abcdefghijklmnopqrstuvwxyz0123456789-_"
VALID_SUBSTITUTIONS_CHARACTERS = (
@ -1095,7 +1095,7 @@ UNIT_STEPS = "steps"
UNIT_VOLT = "V"
UNIT_VOLT_AMPS = "VA"
UNIT_VOLT_AMPS_HOURS = "VAh"
UNIT_VOLT_AMPS_REACTIVE = "VAR"
UNIT_VOLT_AMPS_REACTIVE = "var"
UNIT_VOLT_AMPS_REACTIVE_HOURS = "VARh"
UNIT_WATT = "W"
UNIT_WATT_HOURS = "Wh"

View file

@ -46,7 +46,7 @@ size_t RingBuffer::read(void *data, size_t len, TickType_t ticks_to_wait) {
return bytes_read;
}
size_t RingBuffer::write(void *data, size_t len) {
size_t RingBuffer::write(const void *data, size_t len) {
size_t free = this->free();
if (free < len) {
size_t needed = len - free;
@ -56,7 +56,7 @@ size_t RingBuffer::write(void *data, size_t len) {
return xStreamBufferSend(this->handle_, data, len, 0);
}
size_t RingBuffer::write_without_replacement(void *data, size_t len, TickType_t ticks_to_wait) {
size_t RingBuffer::write_without_replacement(const void *data, size_t len, TickType_t ticks_to_wait) {
return xStreamBufferSend(this->handle_, data, len, ticks_to_wait);
}

View file

@ -37,7 +37,7 @@ class RingBuffer {
* @param len Number of bytes to write
* @return Number of bytes written
*/
size_t write(void *data, size_t len);
size_t write(const void *data, size_t len);
/**
* @brief Writes to the ring buffer without overwriting oldest data.
@ -50,7 +50,7 @@ class RingBuffer {
* @param ticks_to_wait Maximum number of FreeRTOS ticks to wait (default: 0)
* @return Number of bytes written
*/
size_t write_without_replacement(void *data, size_t len, TickType_t ticks_to_wait = 0);
size_t write_without_replacement(const void *data, size_t len, TickType_t ticks_to_wait = 0);
/**
* @brief Returns the number of available bytes in the ring buffer.

View file

@ -39,3 +39,10 @@ esp32_ble_tracker:
- then:
- lambda: |-
ESP_LOGD("ble_auto", "The scan has ended!");
wifi:
ssid: MySSID
password: password1
ota:
- platform: esphome

View file

@ -21,6 +21,9 @@ modbus_controller:
address: 0x2
modbus_id: mod_bus1
allow_duplicate_commands: false
on_online:
then:
logger.log: "Module Online"
- id: modbus_controller2
address: 0x2
modbus_id: mod_bus2

View file

@ -13,4 +13,7 @@ modbus_controller:
address: 0x2
modbus_id: mod_bus1
allow_duplicate_commands: true
on_offline:
then:
logger.log: "Module Offline"
max_cmd_retries: 10

View file

@ -12,10 +12,41 @@ opentherm:
cooling_enable: false
otc_active: false
ch2_active: true
t_room: boiler_sensor
summer_mode_active: true
dhw_block: true
sync_mode: true
output:
- platform: opentherm
t_set:
id: t_set
min_value: 20
auto_max_value: true
zero_means_zero: true
t_set_ch2:
id: t_set_ch2
min_value: 20
max_value: 40
zero_means_zero: true
number:
- platform: opentherm
cooling_control:
name: "Boiler Cooling control signal"
t_dhw_set:
name: "Boiler DHW Setpoint"
max_t_set:
name: "Boiler Max Setpoint"
t_room_set:
name: "Boiler Room Setpoint"
t_room_set_ch2:
name: "Boiler Room Setpoint CH2"
max_rel_mod_level:
name: "Maximum relative modulation level"
otc_hc_ratio:
name: "OTC heat curve ratio"
sensor:
- platform: opentherm
rel_mod_level:
@ -25,6 +56,7 @@ sensor:
dhw_flow_rate:
name: "Boiler Water flow rate in DHW circuit"
t_boiler:
id: "boiler_sensor"
name: "Boiler water temperature"
t_dhw:
name: "Boiler DHW temperature"
@ -74,3 +106,55 @@ sensor:
name: "OTC heat curve ratio upper bound"
otc_hc_ratio_lb:
name: "OTC heat curve ratio lower bound"
binary_sensor:
- platform: opentherm
fault_indication:
name: "Boiler Fault indication"
ch_active:
name: "Boiler Central Heating active"
dhw_active:
name: "Boiler Domestic Hot Water active"
flame_on:
name: "Boiler Flame on"
cooling_active:
name: "Boiler Cooling active"
ch2_active:
name: "Boiler Central Heating 2 active"
diagnostic_indication:
name: "Boiler Diagnostic event"
dhw_present:
name: "Boiler DHW present"
control_type_on_off:
name: "Boiler Control type is on/off"
cooling_supported:
name: "Boiler Cooling supported"
dhw_storage_tank:
name: "Boiler DHW storage tank"
controller_pump_control_allowed:
name: "Boiler Controller pump control allowed"
ch2_present:
name: "Boiler CH2 present"
dhw_setpoint_transfer_enabled:
name: "Boiler DHW setpoint transfer enabled"
max_ch_setpoint_transfer_enabled:
name: "Boiler CH maximum setpoint transfer enabled"
dhw_setpoint_rw:
name: "Boiler DHW setpoint read/write"
max_ch_setpoint_rw:
name: "Boiler CH maximum setpoint read/write"
switch:
- platform: opentherm
ch_enable:
name: "Boiler Central Heating enabled"
restore_mode: RESTORE_DEFAULT_ON
dhw_enable:
name: "Boiler Domestic Hot Water enabled"
cooling_enable:
name: "Boiler Cooling enabled"
restore_mode: ALWAYS_OFF
otc_active:
name: "Boiler Outside temperature compensation active"
ch2_active:
name: "Boiler Central Heating 2 active"