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changes to backend, some refactoring

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This commit is contained in:
Proddy
2022-04-15 13:04:52 +02:00
parent 9e293136b9
commit 4b3b9524ef
13 changed files with 340 additions and 329 deletions
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44
interface/src/project/DashboardData.tsx
View File

@@ -51,7 +51,7 @@ import { formatDurationMin, pluralize } from '../utils';
import { AuthenticatedContext } from '../contexts/authentication';
import { ButtonRow, FormLoader, ValidatedTextField, SectionContent, MessageBox } from '../components';
import { ButtonRow, ValidatedTextField, SectionContent, MessageBox } from '../components';
import * as EMSESP from './api';
@@ -77,7 +77,6 @@ const DashboardData: FC = () => {
const { enqueueSnackbar } = useSnackbar();
const [errorMessage, setErrorMessage] = useState<string>();
const [coreData, setCoreData] = useState<CoreData>({ devices: [], active_sensors: 0, analog_enabled: false });
const [deviceData, setDeviceData] = useState<DeviceData>({ label: '', data: [] });
const [sensorData, setSensorData] = useState<SensorData>({ sensors: [], analogs: [] });
@@ -286,6 +285,11 @@ const DashboardData: FC = () => {
}
);
const paul = () => {
console.log('paul');
sensor_sort.fns.onToggleSort({ sortKey: 'NAME' });
};
const device_select = useRowSelect(
{ nodes: coreData.devices },
{
@@ -338,7 +342,8 @@ const DashboardData: FC = () => {
const handleDownloadCsv = () => {
const columns = [
{ accessor: (dv: any) => dv.id.slice(2), name: 'Entity' },
{ accessor: (dv: any) => formatValue(dv.v, dv.u), name: 'Value' }
{ accessor: (dv: any) => dv.v, name: 'Value' },
{ accessor: (dv: any) => (dv.u >= 1 && dv.u <= 2 ? 'C' : DeviceValueUOM_s[dv.u]), name: 'UoM' }
];
downloadAsCsv(
columns,
@@ -366,9 +371,9 @@ const DashboardData: FC = () => {
try {
setCoreData((await EMSESP.readCoreData()).data);
} catch (error: any) {
setErrorMessage(extractErrorMessage(error, 'Failed to fetch core data'));
enqueueSnackbar(extractErrorMessage(error, 'Failed to fetch core data'), { variant: 'error' });
}
}, []);
}, [enqueueSnackbar]);
useEffect(() => {
fetchCoreData();
@@ -387,7 +392,7 @@ const DashboardData: FC = () => {
try {
setDeviceData((await EMSESP.readDeviceData({ id: unique_id })).data);
} catch (error: any) {
setErrorMessage(extractErrorMessage(error, 'Problem fetching device data'));
enqueueSnackbar(extractErrorMessage(error, 'Problem fetching device data'), { variant: 'error' });
}
};
@@ -395,7 +400,7 @@ const DashboardData: FC = () => {
try {
setSensorData((await EMSESP.readSensorData()).data);
} catch (error: any) {
setErrorMessage(extractErrorMessage(error, 'Problem fetching sensor data'));
enqueueSnackbar(extractErrorMessage(error, 'Problem fetching sensor data'), { variant: 'error' });
}
};
@@ -448,7 +453,7 @@ const DashboardData: FC = () => {
}
setDeviceValue(undefined);
} catch (error: any) {
setErrorMessage(extractErrorMessage(error, 'Problem writing value'));
enqueueSnackbar(extractErrorMessage(error, 'Problem writing value'), { variant: 'error' });
} finally {
refreshData();
setDeviceValue(undefined);
@@ -519,7 +524,7 @@ const DashboardData: FC = () => {
};
const addAnalogSensor = () => {
setAnalog({ id: '0', i: 0, n: '', u: 0, v: 0, o: 0, t: 0, f: 1 });
setAnalog({ id: '0', g: 0, n: '', u: 0, v: 0, o: 0, t: 0, f: 1 });
};
const sendSensor = async () => {
@@ -539,7 +544,7 @@ const DashboardData: FC = () => {
}
setSensor(undefined);
} catch (error: any) {
setErrorMessage(extractErrorMessage(error, 'Problem updating sensor'));
enqueueSnackbar(extractErrorMessage(error, 'Problem updating sensor'), { variant: 'error' });
} finally {
setSensor(undefined);
fetchSensorData();
@@ -648,12 +653,7 @@ const DashboardData: FC = () => {
}
};
const renderCoreData = () => {
if (!coreData) {
return <FormLoader errorMessage={errorMessage} />;
}
return (
const renderCoreData = () => (
<IconContext.Provider value={{ color: 'lightblue', size: '24', style: { verticalAlign: 'middle' } }}>
{coreData.devices.length === 0 && <MessageBox my={2} level="warning" message="Scanning for EMS devices..." />}
@@ -706,7 +706,6 @@ const DashboardData: FC = () => {
</Table>
</IconContext.Provider>
);
};
const renderDeviceData = () => {
if (!device_select.state.id || device_select.state.id === 'sensor') {
@@ -830,7 +829,8 @@ const DashboardData: FC = () => {
fullWidth
style={{ fontSize: '14px', justifyContent: 'flex-start' }}
endIcon={getSortIcon(sensor_sort.state, 'NAME')}
onClick={() => sensor_sort.fns.onToggleSort({ sortKey: 'NAME' })}
// onClick={() => sensor_sort.fns.onToggleSort({ sortKey: 'NAME' })}
onClick={() => paul()}
>
NAME
</Button>
@@ -950,7 +950,7 @@ const DashboardData: FC = () => {
if (analog) {
try {
const response = await EMSESP.writeAnalog({
i: analog.i,
gpio: analog.g,
name: analog.n,
offset: analog.o,
factor: analog.f,
@@ -978,7 +978,7 @@ const DashboardData: FC = () => {
if (analog) {
try {
const response = await EMSESP.writeAnalog({
i: analog.i,
gpio: analog.g,
name: analog.n,
offset: analog.o,
factor: analog.f,
@@ -1011,9 +1011,9 @@ const DashboardData: FC = () => {
<Grid container spacing={2}>
<Grid item>
<ValidatedTextField
name="i"
name="g"
label="GPIO"
value={analog.i}
value={analog.g}
type="number"
variant="outlined"
autoFocus

6
interface/src/project/types.ts
View File

@@ -89,7 +89,7 @@ export interface Sensor {
export interface Analog {
id: string; // id string
i: number; // GPIO
g: number; // GPIO
n: string;
v: number; // is optional
u: number;
@@ -145,7 +145,7 @@ export interface DeviceData {
export interface DeviceEntity {
n: string; // name
v?: any; // value, in any format
v: any; // value, in any format
s: string; // shortname
m: number; // mask
om?: number; // original mask before edits
@@ -278,7 +278,7 @@ export interface WriteValue {
}
export interface WriteAnalog {
i: number;
gpio: number;
name: string;
factor: number;
offset: number;

12
mock-api/server.js
View File

@@ -362,11 +362,11 @@ const emsesp_devices = {
}
const emsesp_coredata = {
// devices: [],
devices: [
{
id: '2',
t: 'Boiler',
s: 'Boiler',
b: 'Nefit',
n: 'GBx72/Trendline/Cerapur/Greenstar Si/27i',
d: 8,
@@ -377,7 +377,6 @@ const emsesp_coredata = {
{
id: '1',
t: 'Thermostat',
s: 'Thermostat',
b: '',
n: 'RC20/Moduline 300',
d: 23,
@@ -388,7 +387,6 @@ const emsesp_coredata = {
{
id: '4',
t: 'Thermostat',
s: 'Thermostat',
b: 'Buderus',
n: 'RC100/Moduline 1000/1010',
d: 16,
@@ -410,10 +408,10 @@ const emsesp_sensordata = {
],
// sensors: [],
analogs: [
{ id: '36', i: 36, n: 'motor', v: 0, u: 0, o: 17, f: 0, t: 0 },
{ id: '37', i: 37, n: 'External switch', v: 13, u: 0, o: 17, f: 0, t: 1 },
{ id: '39', i: 39, n: 'Pulse count', v: 144, u: 0, o: 0, f: 0, t: 2 },
{ id: '40', i: 40, n: 'Pressure', v: 16, u: 17, o: 0, f: 0, t: 3 },
{ id: '1', g: 36, n: 'motor', v: 0, u: 0, o: 17, f: 0, t: 0 },
{ id: '2', g: 37, n: 'External switch', v: 13, u: 0, o: 17, f: 0, t: 1 },
{ id: '3', g: 39, n: 'Pulse count', v: 144, u: 0, o: 0, f: 0, t: 2 },
{ id: '4', g: 40, n: 'Pressure', v: 16, u: 17, o: 0, f: 0, t: 3 },
],
// analogs: [],
}

108
src/analogsensor.cpp
View File

@@ -69,7 +69,7 @@ void AnalogSensor::reload() {
// update existing sensors
bool found = false;
for (const auto & sensor : settings.analogCustomizations) { //search customlist
if (sensor_.id() == sensor.id) {
if (sensor_.gpio() == sensor.gpio) {
// for output sensors set value to new start-value
if ((sensor.type == AnalogType::COUNTER || sensor.type >= AnalogType::DIGITAL_OUT)
&& (sensor_.type() != sensor.type || sensor_.offset() != sensor.offset || sensor_.factor() != sensor.factor)) {
@@ -94,12 +94,12 @@ void AnalogSensor::reload() {
for (const auto & sensor : settings.analogCustomizations) {
bool found = false;
for (const auto & sensor_ : sensors_) {
if (sensor_.id() == sensor.id) {
if (sensor_.gpio() == sensor.gpio) {
found = true;
}
}
if (!found) {
sensors_.emplace_back(sensor.id, sensor.name, sensor.offset, sensor.factor, sensor.uom, sensor.type);
sensors_.emplace_back(sensor.gpio, sensor.name, sensor.offset, sensor.factor, sensor.uom, sensor.type);
sensors_.back().ha_registered = false; // this will trigger recrate of the HA config
if (sensor.type == AnalogType::COUNTER || sensor.type >= AnalogType::DIGITAL_OUT) {
sensors_.back().set_value(sensor.offset);
@@ -112,64 +112,64 @@ void AnalogSensor::reload() {
});
// sort the list based on GPIO (id)
std::sort(sensors_.begin(), sensors_.end(), [](const Sensor & a, const Sensor & b) { return a.id() < b.id(); });
// std::sort(sensors_.begin(), sensors_.end(), [](const Sensor & a, const Sensor & b) { return a.id() < b.id(); });
// activate each sensor
for (auto & sensor : sensors_) {
sensor.ha_registered = false; // force HA configs to be re-created
if (sensor.type() == AnalogType::ADC) {
LOG_DEBUG(F("Adding analog ADC sensor on GPIO%d"), sensor.id());
LOG_DEBUG(F("Adding analog ADC sensor on GPIO%d"), sensor.gpio());
// analogSetPinAttenuation does not work with analogReadMilliVolts
sensor.analog_ = 0; // initialize
sensor.last_reading_ = 0;
} else if (sensor.type() == AnalogType::COUNTER) {
LOG_DEBUG(F("Adding analog I/O Counter sensor on GPIO%d"), sensor.id());
pinMode(sensor.id(), INPUT_PULLUP);
if (sensor.id() == 25 || sensor.id() == 26) {
dacWrite(sensor.id(), 255);
LOG_DEBUG(F("Adding analog I/O Counter sensor on GPIO%d"), sensor.gpio());
pinMode(sensor.gpio(), INPUT_PULLUP);
if (sensor.gpio() == 25 || sensor.gpio() == 26) {
dacWrite(sensor.gpio(), 255);
}
sensor.polltime_ = 0;
sensor.poll_ = digitalRead(sensor.id());
sensor.poll_ = digitalRead(sensor.gpio());
publish_sensor(sensor);
} else if (sensor.type() == AnalogType::TIMER || sensor.type() == AnalogType::RATE) {
LOG_DEBUG(F("Adding analog Timer/Rate sensor on GPIO%d"), sensor.id());
pinMode(sensor.id(), INPUT_PULLUP);
LOG_DEBUG(F("Adding analog Timer/Rate sensor on GPIO%d"), sensor.gpio());
pinMode(sensor.gpio(), INPUT_PULLUP);
sensor.polltime_ = uuid::get_uptime();
sensor.last_polltime_ = uuid::get_uptime();
sensor.poll_ = digitalRead(sensor.id());
sensor.poll_ = digitalRead(sensor.gpio());
sensor.set_offset(0);
sensor.set_value(0);
publish_sensor(sensor);
} else if (sensor.type() == AnalogType::DIGITAL_IN) {
LOG_DEBUG(F("Adding analog Read sensor on GPIO%d"), sensor.id());
pinMode(sensor.id(), INPUT_PULLUP);
sensor.set_value(digitalRead(sensor.id())); // initial value
LOG_DEBUG(F("Adding analog Read sensor on GPIO%d"), sensor.gpio());
pinMode(sensor.gpio(), INPUT_PULLUP);
sensor.set_value(digitalRead(sensor.gpio())); // initial value
sensor.set_uom(0); // no uom, just for safe measures
sensor.polltime_ = 0;
sensor.poll_ = digitalRead(sensor.id());
sensor.poll_ = digitalRead(sensor.gpio());
publish_sensor(sensor);
} else if (sensor.type() == AnalogType::DIGITAL_OUT) {
LOG_DEBUG(F("Adding analog Write sensor on GPIO%d"), sensor.id());
pinMode(sensor.id(), OUTPUT);
if (sensor.id() == 25 || sensor.id() == 26) {
LOG_DEBUG(F("Adding analog Write sensor on GPIO%d"), sensor.gpio());
pinMode(sensor.gpio(), OUTPUT);
if (sensor.gpio() == 25 || sensor.gpio() == 26) {
if (sensor.offset() > 255) {
sensor.set_offset(255);
} else if (sensor.offset() < 0) {
sensor.set_offset(0);
}
dacWrite(sensor.id(), sensor.offset());
dacWrite(sensor.gpio(), sensor.offset());
sensor.set_value(sensor.offset());
} else {
digitalWrite(sensor.id(), sensor.offset() > 0 ? 1 : 0);
sensor.set_value(digitalRead(sensor.id()));
digitalWrite(sensor.gpio(), sensor.offset() > 0 ? 1 : 0);
sensor.set_value(digitalRead(sensor.gpio()));
}
sensor.set_uom(0); // no uom, just for safe measures
publish_sensor(sensor);
} else if (sensor.type() >= AnalogType::PWM_0) {
LOG_DEBUG(F("Adding PWM output sensor on GPIO%d"), sensor.id());
LOG_DEBUG(F("Adding PWM output sensor on GPIO%d"), sensor.gpio());
uint channel = sensor.type() - AnalogType::PWM_0;
ledcSetup(channel, sensor.factor(), 13);
ledcAttachPin(sensor.id(), channel);
ledcAttachPin(sensor.gpio(), channel);
if (sensor.offset() > 100) {
sensor.set_offset(100);
} else if (sensor.offset() < 0) {
@@ -193,7 +193,7 @@ void AnalogSensor::measure() {
// go through the list of adc sensors
for (auto & sensor : sensors_) {
if (sensor.type() == AnalogType::ADC) {
uint16_t a = analogReadMilliVolts(sensor.id()); // e.g. ADC1_CHANNEL_0_GPIO_NUM
uint16_t a = analogReadMilliVolts(sensor.gpio()); // e.g. ADC1_CHANNEL_0_GPIO_NUM
if (!sensor.analog_) { // init first time
sensor.analog_ = a;
sensor.sum_ = a * 512;
@@ -218,7 +218,7 @@ void AnalogSensor::measure() {
if (sensor.type() == AnalogType::DIGITAL_IN || sensor.type() == AnalogType::COUNTER || sensor.type() == AnalogType::TIMER
|| sensor.type() == AnalogType::RATE) {
auto old_value = sensor.value(); // remember current value before reading
auto current_reading = digitalRead(sensor.id());
auto current_reading = digitalRead(sensor.gpio());
if (sensor.poll_ != current_reading) { // check for pinchange
sensor.polltime_ = uuid::get_uptime(); // remember time of pinchange
sensor.poll_ = current_reading;
@@ -258,17 +258,17 @@ void AnalogSensor::loop() {
}
// update analog information name and offset
bool AnalogSensor::update(uint8_t id, const std::string & name, float offset, float factor, uint8_t uom, int8_t type) {
bool AnalogSensor::update(uint8_t gpio, const std::string & name, float offset, float factor, uint8_t uom, int8_t type) {
boolean found_sensor = false; // see if we can find the sensor in our customization list
EMSESP::webCustomizationService.update(
[&](WebCustomization & settings) {
for (auto & AnalogCustomization : settings.analogCustomizations) {
if (AnalogCustomization.id == id) {
if (AnalogCustomization.gpio == gpio) {
found_sensor = true; // found the record
// see if it's marked for deletion
if (type == AnalogType::MARK_DELETED) {
LOG_DEBUG(F("Removing analog sensor ID %d"), id);
LOG_DEBUG(F("Removing analog sensor GPIO %d"), gpio);
settings.analogCustomizations.remove(AnalogCustomization);
} else {
// update existing record
@@ -277,7 +277,7 @@ bool AnalogSensor::update(uint8_t id, const std::string & name, float offset, fl
AnalogCustomization.factor = factor;
AnalogCustomization.uom = uom;
AnalogCustomization.type = type;
LOG_DEBUG(F("Customizing existing analog sensor ID %d"), id);
LOG_DEBUG(F("Customizing existing analog GPIO %d"), gpio);
}
return StateUpdateResult::CHANGED; // persist the change
}
@@ -288,7 +288,7 @@ bool AnalogSensor::update(uint8_t id, const std::string & name, float offset, fl
// if the sensor exists and we're using HA, delete the old HA record
if (found_sensor && Mqtt::ha_enabled()) {
remove_ha_topic(id); // id is the GPIO
remove_ha_topic(gpio); // the GPIO
}
// we didn't find it, it's new, so create and store it
@@ -296,14 +296,14 @@ bool AnalogSensor::update(uint8_t id, const std::string & name, float offset, fl
EMSESP::webCustomizationService.update(
[&](WebCustomization & settings) {
auto newSensor = AnalogCustomization();
newSensor.id = id;
newSensor.gpio = gpio;
newSensor.name = name;
newSensor.offset = offset;
newSensor.factor = factor;
newSensor.uom = uom;
newSensor.type = type;
settings.analogCustomizations.push_back(newSensor);
LOG_DEBUG(F("Adding new customization for analog sensor ID %d"), id);
LOG_DEBUG(F("Adding new customization for analog sensor GPIO %d"), gpio);
return StateUpdateResult::CHANGED; // persist the change
},
"local");
@@ -339,15 +339,15 @@ void AnalogSensor::publish_sensor(const Sensor & sensor) const {
}
// send empty config topic to remove the entry from HA
void AnalogSensor::remove_ha_topic(const uint8_t id) const {
void AnalogSensor::remove_ha_topic(const uint8_t gpio) const {
if (!Mqtt::ha_enabled()) {
return;
}
#ifdef EMSESP_DEBUG
LOG_DEBUG(F("Removing HA config for analog sensor ID %d"), id);
LOG_DEBUG(F("Removing HA config for analog sensor GPIO %d"), gpio);
#endif
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf(topic, sizeof(topic), "sensor/%s/analogsensor_%d/config", Mqtt::base().c_str(), id);
snprintf(topic, sizeof(topic), "sensor/%s/analogsensor_%d/config", Mqtt::base().c_str(), gpio);
Mqtt::publish_ha(topic);
}
@@ -372,7 +372,7 @@ void AnalogSensor::publish_values(const bool force) {
if (Mqtt::is_nested() || Mqtt::ha_enabled()) {
// nested
char s[10];
JsonObject dataSensor = doc.createNestedObject(Helpers::smallitoa(s, sensor.id()));
JsonObject dataSensor = doc.createNestedObject(Helpers::smallitoa(s, sensor.gpio()));
dataSensor["name"] = sensor.name();
switch (sensor.type()) {
case AnalogType::COUNTER:
@@ -391,7 +391,7 @@ void AnalogSensor::publish_values(const bool force) {
// create HA config
if (Mqtt::ha_enabled() && (!sensor.ha_registered || force)) {
LOG_DEBUG(F("Recreating HA config for analog sensor ID %d"), sensor.id());
LOG_DEBUG(F("Recreating HA config for analog sensor GPIO %d"), sensor.gpio());
StaticJsonDocument<EMSESP_JSON_SIZE_MEDIUM> config;
@@ -400,13 +400,13 @@ void AnalogSensor::publish_values(const bool force) {
config["stat_t"] = stat_t;
char str[50];
snprintf(str, sizeof(str), "{{value_json['%d'].value}}", sensor.id());
snprintf(str, sizeof(str), "{{value_json['%d'].value}}", sensor.gpio());
config["val_tpl"] = str;
snprintf(str, sizeof(str), "Analog Sensor %s", sensor.name().c_str());
config["name"] = str;
snprintf(str, sizeof(str), "analogsensor_%d", sensor.id());
snprintf(str, sizeof(str), "analogsensor_%d", sensor.gpio());
config["uniq_id"] = str;
JsonObject dev = config.createNestedObject("dev");
@@ -414,7 +414,7 @@ void AnalogSensor::publish_values(const bool force) {
ids.add("ems-esp");
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf(topic, sizeof(topic), "sensor/%s/analogsensor_%d/config", Mqtt::base().c_str(), sensor.id());
snprintf(topic, sizeof(topic), "sensor/%s/analogsensor_%d/config", Mqtt::base().c_str(), sensor.gpio());
Mqtt::publish_ha(topic, config.as<JsonObject>());
@@ -437,7 +437,7 @@ void AnalogSensor::publish_values(const bool force) {
bool AnalogSensor::get_value_info(JsonObject & output, const char * cmd, const int8_t id) const {
for (const auto & sensor : sensors_) {
if (strcmp(cmd, sensor.name().c_str()) == 0) {
output["id"] = sensor.id();
output["gpio"] = sensor.gpio();
output["name"] = sensor.name();
output["type"] = sensor.type();
output["uom"] = sensor.uom();
@@ -460,7 +460,7 @@ bool AnalogSensor::command_info(const char * value, const int8_t id, JsonObject
for (const auto & sensor : sensors_) {
if (id == -1) { // show number and id
JsonObject dataSensor = output.createNestedObject(sensor.name());
dataSensor["id"] = sensor.id();
dataSensor["gpio"] = sensor.gpio();
dataSensor["type"] = FL_(enum_sensortype)[sensor.type()];
if (sensor.type() == AnalogType::ADC) {
dataSensor["uom"] = EMSdevice::uom_to_string(sensor.uom());
@@ -486,8 +486,8 @@ bool AnalogSensor::command_info(const char * value, const int8_t id, JsonObject
}
// this creates the sensor, initializing everything
AnalogSensor::Sensor::Sensor(const uint8_t id, const std::string & name, const float offset, const float factor, const uint8_t uom, const int8_t type)
: id_(id)
AnalogSensor::Sensor::Sensor(const uint8_t gpio, const std::string & name, const float offset, const float factor, const uint8_t uom, const int8_t type)
: gpio_(gpio)
, name_(name)
, offset_(offset)
, factor_(factor)
@@ -500,20 +500,20 @@ AnalogSensor::Sensor::Sensor(const uint8_t id, const std::string & name, const f
std::string AnalogSensor::Sensor::name() const {
if (name_.empty()) {
char name[50];
snprintf(name, sizeof(name), "Analog Sensor GPIO%d", id_);
snprintf(name, sizeof(name), "Analog Sensor GPIO%d", gpio_);
return name;
}
return name_;
}
// set the counter value, id is gpio-no
bool AnalogSensor::command_setvalue(const char * value, const int8_t id) {
bool AnalogSensor::command_setvalue(const char * value, const int8_t gpio) {
float val;
if (!Helpers::value2float(value, val)) {
return false;
}
for (auto & sensor : sensors_) {
if (sensor.id() == id) {
if (sensor.gpio() == gpio) {
if (sensor.type() == AnalogType::COUNTER) {
if (val < 0 || value[0] == '+') { // sign corrects values
sensor.set_offset(sensor.value() + val);
@@ -529,18 +529,18 @@ bool AnalogSensor::command_setvalue(const char * value, const int8_t id) {
return true;
} else if (sensor.type() == AnalogType::DIGITAL_OUT) {
uint8_t v = val;
if (sensor.id() == 25 || sensor.id() == 26) {
if (sensor.gpio() == 25 || sensor.gpio() == 26) {
sensor.set_offset(v);
sensor.set_value(v);
pinMode(sensor.id(), OUTPUT);
dacWrite(sensor.id(), sensor.offset());
pinMode(sensor.gpio(), OUTPUT);
dacWrite(sensor.gpio(), sensor.offset());
publish_sensor(sensor);
return true;
} else if (v == 0 || v == 1) {
sensor.set_offset(v);
sensor.set_value(v);
pinMode(sensor.id(), OUTPUT);
digitalWrite(sensor.id(), sensor.offset() > 0 ? 1 : 0);
pinMode(sensor.gpio(), OUTPUT);
digitalWrite(sensor.gpio(), sensor.offset() > 0 ? 1 : 0);
publish_sensor(sensor);
return true;
}

12
src/analogsensor.h
View File

@@ -36,7 +36,7 @@ class AnalogSensor {
public:
class Sensor {
public:
Sensor(const uint8_t id, const std::string & name, const float offset, const float factor, const uint8_t uom, const int8_t type);
Sensor(const uint8_t gpio, const std::string & name, const float offset, const float factor, const uint8_t uom, const int8_t type);
~Sensor() = default;
void set_offset(const float offset) {
@@ -48,8 +48,8 @@ class AnalogSensor {
name_ = name;
}
uint8_t id() const {
return id_;
uint8_t gpio() const {
return gpio_;
}
float value() const {
@@ -99,7 +99,7 @@ class AnalogSensor {
uint32_t last_polltime_ = 0; // for timer
private:
uint8_t id_;
uint8_t gpio_;
std::string name_;
float offset_;
float factor_;
@@ -157,7 +157,7 @@ class AnalogSensor {
return sensors_.size();
}
bool update(uint8_t id, const std::string & name, float offset, float factor, uint8_t uom, int8_t type);
bool update(uint8_t gpio, const std::string & name, float offset, float factor, uint8_t uom, int8_t type);
bool get_value_info(JsonObject & output, const char * cmd, const int8_t id) const;
#ifdef EMSESP_DEBUG
@@ -171,7 +171,7 @@ class AnalogSensor {
static uuid::log::Logger logger_;
void remove_ha_topic(const uint8_t id) const;
bool command_setvalue(const char * value, const int8_t id);
bool command_setvalue(const char * value, const int8_t gpio);
void measure();
bool command_info(const char * value, const int8_t id, JsonObject & output) const;
bool command_commands(const char * value, const int8_t id, JsonObject & output);

72
src/dallassensor.cpp
View File

@@ -149,7 +149,7 @@ void DallasSensor::loop() {
// check if we already have this sensor
bool found = false;
for (auto & sensor : sensors_) {
if (sensor.id() == get_id(addr)) {
if (sensor.internal_id() == get_id(addr)) {
t += sensor.offset();
if (t != sensor.temperature_c) {
publish_sensor(sensor);
@@ -171,7 +171,7 @@ void DallasSensor::loop() {
sensors_.back().apply_customization();
publish_sensor(sensors_.back()); // call publish single
// sort the sensors based on name
std::sort(sensors_.begin(), sensors_.end(), [](const Sensor & a, const Sensor & b) { return a.name() < b.name(); });
// std::sort(sensors_.begin(), sensors_.end(), [](const Sensor & a, const Sensor & b) { return a.name() < b.name(); });
}
} else {
sensorfails_++;
@@ -180,12 +180,12 @@ void DallasSensor::loop() {
default:
sensorfails_++;
LOG_ERROR(F("Unknown dallas sensor %s"), Sensor(addr).id_str().c_str());
LOG_ERROR(F("Unknown dallas sensor %s"), Sensor(addr).id().c_str());
break;
}
} else {
sensorfails_++;
LOG_ERROR(F("Invalid dallas sensor %s"), Sensor(addr).id_str().c_str());
LOG_ERROR(F("Invalid dallas sensor %s"), Sensor(addr).id().c_str());
}
} else {
if (!parasite_) {
@@ -229,7 +229,7 @@ bool DallasSensor::temperature_convert_complete() {
int16_t DallasSensor::get_temperature_c(const uint8_t addr[]) {
#ifndef EMSESP_STANDALONE
if (!bus_.reset()) {
LOG_ERROR(F("Bus reset failed before reading scratchpad from %s"), Sensor(addr).id_str().c_str());
LOG_ERROR(F("Bus reset failed before reading scratchpad from %s"), Sensor(addr).id().c_str());
return EMS_VALUE_SHORT_NOTSET;
}
YIELD;
@@ -241,7 +241,7 @@ int16_t DallasSensor::get_temperature_c(const uint8_t addr[]) {
YIELD;
if (!bus_.reset()) {
LOG_ERROR(F("Bus reset failed after reading scratchpad from %s"), Sensor(addr).id_str().c_str());
LOG_ERROR(F("Bus reset failed after reading scratchpad from %s"), Sensor(addr).id().c_str());
return EMS_VALUE_SHORT_NOTSET;
}
YIELD;
@@ -257,7 +257,7 @@ int16_t DallasSensor::get_temperature_c(const uint8_t addr[]) {
scratchpad[6],
scratchpad[7],
scratchpad[8],
Sensor(addr).id_str().c_str());
Sensor(addr).id().c_str());
return EMS_VALUE_SHORT_NOTSET;
}
@@ -290,15 +290,15 @@ int16_t DallasSensor::get_temperature_c(const uint8_t addr[]) {
}
// update dallas information name and offset
bool DallasSensor::update(const std::string & id_str, const std::string & name, int16_t offset) {
bool DallasSensor::update(const std::string & id, const std::string & name, int16_t offset) {
// find the sensor
for (auto & sensor : sensors_) {
if (sensor.id_str() == id_str) {
if (sensor.id() == id) {
// found a match, update the sensor object
// if HA is enabled then delete the old record
if (Mqtt::ha_enabled()) {
remove_ha_topic(id_str);
remove_ha_topic(id);
}
sensor.set_name(name);
@@ -310,21 +310,21 @@ bool DallasSensor::update(const std::string & id_str, const std::string & name,
// look it up to see if it exists
bool found = false;
for (auto & SensorCustomization : settings.sensorCustomizations) {
if (SensorCustomization.id_str == id_str) {
if (SensorCustomization.id == id) {
SensorCustomization.name = name;
SensorCustomization.offset = offset;
found = true;
LOG_DEBUG(F("Customizing existing sensor ID %s"), id_str.c_str());
LOG_DEBUG(F("Customizing existing sensor ID %s"), id.c_str());
break;
}
}
if (!found) {
SensorCustomization newSensor = SensorCustomization();
newSensor.id_str = id_str;
newSensor.id = id;
newSensor.name = name;
newSensor.offset = offset;
settings.sensorCustomizations.push_back(newSensor);
LOG_DEBUG(F("Adding new customization for sensor ID %s"), id_str.c_str());
LOG_DEBUG(F("Adding new customization for sensor ID %s"), id.c_str());
}
sensor.ha_registered = false; // it's changed so we may need to recreate the HA config
return StateUpdateResult::CHANGED;
@@ -361,7 +361,7 @@ bool DallasSensor::command_info(const char * value, const int8_t id, JsonObject
for (const auto & sensor : sensors_) {
if (id == -1) { // show number and id
JsonObject dataSensor = output.createNestedObject(sensor.name());
dataSensor["id_str"] = sensor.id_str();
dataSensor["id"] = sensor.id();
if (Helpers::hasValue(sensor.temperature_c)) {
dataSensor["temp"] = Helpers::round2((float)(sensor.temperature_c), 10, EMSESP::system_.fahrenheit() ? 2 : 0);
}
@@ -377,7 +377,7 @@ bool DallasSensor::command_info(const char * value, const int8_t id, JsonObject
bool DallasSensor::get_value_info(JsonObject & output, const char * cmd, const int8_t id) {
for (const auto & sensor : sensors_) {
if (strcmp(cmd, sensor.name().c_str()) == 0) {
output["id_str"] = sensor.id_str();
output["id"] = sensor.id();
output["name"] = sensor.name();
if (Helpers::hasValue(sensor.temperature_c)) {
output["value"] = Helpers::round2((float)(sensor.temperature_c), 10, EMSESP::system_.fahrenheit() ? 2 : 0);
@@ -408,15 +408,15 @@ void DallasSensor::publish_sensor(const Sensor & sensor) {
}
// send empty config topic to remove the entry from HA
void DallasSensor::remove_ha_topic(const std::string & id_str) {
void DallasSensor::remove_ha_topic(const std::string & id) {
if (!Mqtt::ha_enabled()) {
return;
}
#ifdef EMSESP_DEBUG
LOG_DEBUG(F("Removing HA config for temperature sensor ID %s"), id_str.c_str());
LOG_DEBUG(F("Removing HA config for temperature sensor ID %s"), id.c_str());
#endif
// use '_' as HA doesn't like '-' in the topic name
std::string sensorid = id_str;
std::string sensorid = id;
std::replace(sensorid.begin(), sensorid.end(), '-', '_');
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf(topic, sizeof(topic), "sensor/%s/dallassensor_%s/config", Mqtt::base().c_str(), sensorid.c_str());
@@ -442,7 +442,7 @@ void DallasSensor::publish_values(const bool force) {
for (auto & sensor : sensors_) {
bool has_value = Helpers::hasValue(sensor.temperature_c);
if (Mqtt::is_nested() || Mqtt::ha_enabled()) {
JsonObject dataSensor = doc.createNestedObject(sensor.id_str());
JsonObject dataSensor = doc.createNestedObject(sensor.id());
dataSensor["name"] = sensor.name();
if (has_value) {
dataSensor["temp"] = Helpers::round2((float)(sensor.temperature_c), 10, EMSESP::system_.fahrenheit() ? 2 : 0);
@@ -455,7 +455,7 @@ void DallasSensor::publish_values(const bool force) {
// to e.g. homeassistant/sensor/ems-esp/dallassensor_28-233D-9497-0C03/config
if (Mqtt::ha_enabled()) {
if (!sensor.ha_registered || force) {
LOG_DEBUG(F("Recreating HA config for sensor ID %s"), sensor.id_str().c_str());
LOG_DEBUG(F("Recreating HA config for sensor ID %s"), sensor.id().c_str());
StaticJsonDocument<EMSESP_JSON_SIZE_MEDIUM> config;
config["dev_cla"] = FJSON("temperature");
@@ -467,13 +467,13 @@ void DallasSensor::publish_values(const bool force) {
config["unit_of_meas"] = EMSdevice::uom_to_string(DeviceValueUOM::DEGREES);
char str[50];
snprintf(str, sizeof(str), "{{value_json['%s'].temp}}", sensor.id_str().c_str());
snprintf(str, sizeof(str), "{{value_json['%s'].temp}}", sensor.id().c_str());
config["val_tpl"] = str;
snprintf(str, sizeof(str), "Temperature Sensor %s", sensor.name().c_str());
config["name"] = str;
snprintf(str, sizeof(str), "dallasensor_%s", sensor.id_str().c_str());
snprintf(str, sizeof(str), "dallasensor_%s", sensor.id().c_str());
config["uniq_id"] = str;
JsonObject dev = config.createNestedObject("dev");
@@ -482,7 +482,7 @@ void DallasSensor::publish_values(const bool force) {
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
// use '_' as HA doesn't like '-' in the topic name
std::string sensorid = sensor.id_str();
std::string sensorid = sensor.id();
std::replace(sensorid.begin(), sensorid.end(), '-', '_');
snprintf(topic, sizeof(topic), "sensor/%s/dallassensor_%s/config", Mqtt::base().c_str(), sensorid.c_str());
@@ -500,18 +500,18 @@ void DallasSensor::publish_values(const bool force) {
// skip crc from id
DallasSensor::Sensor::Sensor(const uint8_t addr[])
: id_(((uint64_t)addr[0] << 48) | ((uint64_t)addr[1] << 40) | ((uint64_t)addr[2] << 32) | ((uint64_t)addr[3] << 24) | ((uint64_t)addr[4] << 16)
: internal_id_(((uint64_t)addr[0] << 48) | ((uint64_t)addr[1] << 40) | ((uint64_t)addr[2] << 32) | ((uint64_t)addr[3] << 24) | ((uint64_t)addr[4] << 16)
| ((uint64_t)addr[5] << 8) | ((uint64_t)addr[6])) {
// create ID string
char id[20];
snprintf(id,
sizeof(id),
char id_str[20];
snprintf(id_str,
sizeof(id_str),
"%02X-%04X-%04X-%04X",
(unsigned int)(id_ >> 48) & 0xFF,
(unsigned int)(id_ >> 32) & 0xFFFF,
(unsigned int)(id_ >> 16) & 0xFFFF,
(unsigned int)(id_)&0xFFFF);
id_str_ = std::string(id);
(unsigned int)(internal_id_ >> 48) & 0xFF,
(unsigned int)(internal_id_ >> 32) & 0xFFFF,
(unsigned int)(internal_id_ >> 16) & 0xFFFF,
(unsigned int)(internal_id_)&0xFFFF);
id_ = std::string(id_str);
name_ = std::string{}; // name (alias) is empty
offset_ = 0; // 0 degrees offset
}
@@ -525,7 +525,7 @@ uint64_t DallasSensor::get_id(const uint8_t addr[]) {
// if empty, return the ID as a string
std::string DallasSensor::Sensor::name() const {
if (name_.empty()) {
return id_str_;
return id_;
}
return name_;
}
@@ -538,9 +538,9 @@ bool DallasSensor::Sensor::apply_customization() {
if (!sensors.empty()) {
for (const auto & sensor : sensors) {
#if defined(EMSESP_DEBUG)
LOG_DEBUG(F("Loading customization for dallas sensor %s"), sensor.id_str.c_str());
LOG_DEBUG(F("Loading customization for dallas sensor %s"), sensor.id.c_str());
#endif
if (id_str_ == sensor.id_str) {
if (id_ == sensor.id) {
set_name(sensor.name);
set_offset(sensor.offset);
return true;

14
src/dallassensor.h
View File

@@ -40,12 +40,12 @@ class DallasSensor {
Sensor(const uint8_t addr[]);
~Sensor() = default;
uint64_t id() const {
return id_;
uint64_t internal_id() const {
return internal_id_;
}
std::string id_str() const {
return id_str_;
std::string id() const {
return id_;
}
int16_t offset() const {
@@ -67,8 +67,8 @@ class DallasSensor {
bool ha_registered = false;
private:
uint64_t id_;
std::string id_str_;
uint64_t internal_id_;
std::string id_;
std::string name_;
int16_t offset_;
};
@@ -109,7 +109,7 @@ class DallasSensor {
return sensors_.size();
}
bool update(const std::string & id_str, const std::string & name, int16_t offset);
bool update(const std::string & id, const std::string & name, int16_t offset);
#ifdef EMSESP_DEBUG
void test();

28
src/emsdevice.cpp
View File

@@ -656,15 +656,12 @@ void EMSdevice::generate_values_web(JsonObject & output) {
output["label"] = to_string_short();
JsonArray data = output.createNestedArray("data");
// do two passes. First for all entities marked as favorites, then for all others. This sorts the list.
for (int8_t fav = 1; fav >= 0; fav--) {
for (auto & dv : devicevalues_) {
// check conditions:
// 1. full_name cannot be empty
// 2. it must have a valid value, if it is not a command like 'reset'
// 3. show favorites first
bool show = (fav && dv.has_state(DeviceValueState::DV_FAVORITE)) || (!fav && !dv.has_state(DeviceValueState::DV_FAVORITE));
if (show && !dv.has_state(DeviceValueState::DV_WEB_EXCLUDE) && dv.full_name && (dv.hasValue() || (dv.type == DeviceValueType::CMD))) {
if (!dv.has_state(DeviceValueState::DV_WEB_EXCLUDE) && dv.full_name && (dv.hasValue() || (dv.type == DeviceValueType::CMD))) {
JsonObject obj = data.createNestedObject(); // create the object, we know there is a value
uint8_t fahrenheit = 0;
@@ -710,6 +707,9 @@ void EMSdevice::generate_values_web(JsonObject & output) {
} else if ((dv.type == DeviceValueType::TIME) && Helpers::hasValue(*(uint32_t *)(dv.value_p))) {
uint32_t time_value = *(uint32_t *)(dv.value_p);
obj["v"] = (divider > 0) ? time_value / divider : time_value; // sometimes we need to divide by 60
} else {
// must have a value for sorting to work
obj["v"] = "";
}
}
@@ -718,13 +718,13 @@ void EMSdevice::generate_values_web(JsonObject & output) {
auto mask = Helpers::hextoa((uint8_t)(dv.state >> 4), false); // create mask to a 2-char string
// add name, prefixing the tag if it exists
// add name, prefixing the tag if it exists. This is the id used for the table sorting
if ((dv.tag == DeviceValueTAG::TAG_NONE) || tag_to_string(dv.tag).empty()) {
obj["n"] = mask + read_flash_string(dv.full_name);
obj["id"] = mask + read_flash_string(dv.full_name);
} else if (dv.tag < DeviceValueTAG::TAG_HC1) {
obj["n"] = mask + tag_to_string(dv.tag) + " " + read_flash_string(dv.full_name);
obj["id"] = mask + tag_to_string(dv.tag) + " " + read_flash_string(dv.full_name);
} else {
obj["n"] = mask + tag_to_string(dv.tag) + " " + read_flash_string(dv.full_name);
obj["id"] = mask + tag_to_string(dv.tag) + " " + read_flash_string(dv.full_name);
}
// add commands and options
@@ -774,7 +774,6 @@ void EMSdevice::generate_values_web(JsonObject & output) {
}
}
}
}
// as generate_values_web() but stripped down to only show all entities and their state
// this is used only for WebCustomizationService::device_entities()
@@ -838,19 +837,22 @@ void EMSdevice::generate_values_web_all(JsonArray & output) {
obj["v"] = (divider > 0) ? time_value / divider : time_value * factor; // sometimes we need to divide by 60
}
}
} else {
// must always have v for sorting to work in web
obj["v"] = "";
}
// add name, prefixing the tag if it exists
// add name, prefixing the tag if it exists as the id (key for table sorting)
if (dv.full_name) {
if ((dv.tag == DeviceValueTAG::TAG_NONE) || tag_to_string(dv.tag).empty()) {
obj["n"] = dv.full_name;
obj["id"] = dv.full_name;
} else {
char name[50];
snprintf(name, sizeof(name), "%s %s", tag_to_string(dv.tag).c_str(), read_flash_string(dv.full_name).c_str());
obj["n"] = name;
obj["id"] = name;
}
} else {
obj["n"] = "";
obj["id"] = "";
}
// shortname

4
src/emsesp.cpp
View File

@@ -432,12 +432,12 @@ void EMSESP::show_sensor_values(uuid::console::Shell & shell) {
(fahrenheit == 0) ? 'C' : 'F',
COLOR_RESET,
Helpers::render_value(s2, sensor.offset(), 10, fahrenheit),
sensor.id_str().c_str());
sensor.id().c_str());
} else {
shell.printfln(F(" %s (offset %s, ID: %s)"),
sensor.name().c_str(),
Helpers::render_value(s, sensor.offset(), 10, fahrenheit),
sensor.id_str().c_str());
sensor.id().c_str());
}
}
shell.println();

4
src/system.cpp
View File

@@ -1036,7 +1036,7 @@ bool System::command_customizations(const char * value, const int8_t id, JsonObj
JsonArray sensorsJson = node.createNestedArray("sensors");
for (const auto & sensor : settings.sensorCustomizations) {
JsonObject sensorJson = sensorsJson.createNestedObject();
sensorJson["id_str"] = sensor.id_str; // key, is
sensorJson["id"] = sensor.id; // key
sensorJson["name"] = sensor.name; // n
sensorJson["offset"] = sensor.offset; // o
}
@@ -1044,7 +1044,7 @@ bool System::command_customizations(const char * value, const int8_t id, JsonObj
JsonArray analogJson = node.createNestedArray("analogs");
for (const AnalogCustomization & sensor : settings.analogCustomizations) {
JsonObject sensorJson = analogJson.createNestedObject();
sensorJson["gpio"] = sensor.id;
sensorJson["gpio"] = sensor.gpio;
sensorJson["name"] = sensor.name;
if (EMSESP::system_.enum_format() == ENUM_FORMAT_INDEX) {
sensorJson["type"] = sensor.type;

8
src/web/WebCustomizationService.cpp
View File

@@ -61,7 +61,7 @@ void WebCustomization::read(WebCustomization & settings, JsonObject & root) {
JsonArray sensorsJson = root.createNestedArray("sensors");
for (const SensorCustomization & sensor : settings.sensorCustomizations) {
JsonObject sensorJson = sensorsJson.createNestedObject();
sensorJson["id_str"] = sensor.id_str; // is
sensorJson["id"] = sensor.id; // is
sensorJson["name"] = sensor.name; // n
sensorJson["offset"] = sensor.offset; // o
}
@@ -70,7 +70,7 @@ void WebCustomization::read(WebCustomization & settings, JsonObject & root) {
JsonArray analogJson = root.createNestedArray("analogs");
for (const AnalogCustomization & sensor : settings.analogCustomizations) {
JsonObject sensorJson = analogJson.createNestedObject();
sensorJson["id"] = sensor.id; // i
sensorJson["gpio"] = sensor.gpio; // g
sensorJson["name"] = sensor.name; // n
sensorJson["offset"] = sensor.offset; // o
sensorJson["factor"] = sensor.factor; // f
@@ -101,7 +101,7 @@ StateUpdateResult WebCustomization::update(JsonObject & root, WebCustomization &
for (const JsonObject sensorJson : root["sensors"].as<JsonArray>()) {
// create each of the sensor, overwritting any previous settings
auto sensor = SensorCustomization();
sensor.id_str = sensorJson["id_str"].as<std::string>();
sensor.id = sensorJson["id"].as<std::string>();
sensor.name = sensorJson["name"].as<std::string>();
sensor.offset = sensorJson["offset"];
settings.sensorCustomizations.push_back(sensor); // add to list
@@ -114,7 +114,7 @@ StateUpdateResult WebCustomization::update(JsonObject & root, WebCustomization &
for (const JsonObject analogJson : root["analogs"].as<JsonArray>()) {
// create each of the sensor, overwritting any previous settings
auto sensor = AnalogCustomization();
sensor.id = analogJson["id"];
sensor.gpio = analogJson["gpio"];
sensor.name = analogJson["name"].as<std::string>();
sensor.offset = analogJson["offset"];
sensor.factor = analogJson["factor"];

6
src/web/WebCustomizationService.h
View File

@@ -35,14 +35,14 @@ namespace emsesp {
// Customization for dallas sensor
class SensorCustomization {
public:
std::string id_str;
std::string id;
std::string name;
uint16_t offset;
};
class AnalogCustomization {
public:
uint8_t id;
uint8_t gpio;
std::string name;
float offset;
float factor;
@@ -51,7 +51,7 @@ class AnalogCustomization {
// used for removing from a list
bool operator==(const AnalogCustomization & a) const {
return id == a.id;
return gpio == a.gpio;
}
bool operator!=(const AnalogCustomization & a) const {
return !operator==(a);

27
src/web/WebDataService.cpp
View File

@@ -76,10 +76,11 @@ void WebDataService::core_data(AsyncWebServerRequest * request) {
// list is already sorted by device type
// Ignore Contoller
JsonArray devices = root.createNestedArray("devices");
char buffer[3];
for (const auto & emsdevice : EMSESP::emsdevices) {
if (emsdevice && (emsdevice->device_type() != EMSdevice::DeviceType::CONTROLLER || emsdevice->count_entities() > 0)) {
JsonObject obj = devices.createNestedObject();
obj["i"] = emsdevice->unique_id(); // a unique id
obj["id"] = Helpers::smallitoa(buffer, emsdevice->unique_id()); // a unique id as a string
obj["t"] = emsdevice->device_type_name(); // type
obj["b"] = emsdevice->brand_to_string(); // brand
obj["n"] = emsdevice->name(); // name
@@ -110,7 +111,7 @@ void WebDataService::sensor_data(AsyncWebServerRequest * request) {
if (EMSESP::dallassensor_.have_sensors()) {
for (const auto & sensor : EMSESP::dallassensor_.sensors()) {
JsonObject obj = sensors.createNestedObject();
obj["is"] = sensor.id_str(); // id
obj["id"] = sensor.id(); // id as string
obj["n"] = sensor.name(); // name
if (EMSESP::system_.fahrenheit()) {
if (Helpers::hasValue(sensor.temperature_c)) {
@@ -129,14 +130,16 @@ void WebDataService::sensor_data(AsyncWebServerRequest * request) {
}
// analog sensors
// assume list is already sorted by id
JsonArray analogs = root.createNestedArray("analogs");
if (EMSESP::analog_enabled() && EMSESP::analogsensor_.have_sensors()) {
uint8_t count = 0;
char buffer[3];
for (const auto & sensor : EMSESP::analogsensor_.sensors()) {
// don't send if it's marked for removal
if (sensor.type() != AnalogSensor::AnalogType::MARK_DELETED) {
JsonObject obj = analogs.createNestedObject();
obj["i"] = sensor.id();
obj["id"] = Helpers::smallitoa(buffer, ++count); // needed for sorting table
obj["g"] = sensor.gpio();
obj["n"] = sensor.name();
obj["u"] = sensor.uom();
obj["o"] = sensor.offset();
@@ -145,6 +148,8 @@ void WebDataService::sensor_data(AsyncWebServerRequest * request) {
if (sensor.type() != AnalogSensor::AnalogType::NOTUSED) {
obj["v"] = Helpers::round2(sensor.value(), 0); // is optional and is a float
} else {
obj["v"] = 0; // must have a value for web sorting to work
}
}
}
@@ -169,6 +174,12 @@ void WebDataService::device_data(AsyncWebServerRequest * request, JsonVariant &
#ifndef EMSESP_STANDALONE
JsonObject output = response->getRoot();
emsdevice->generate_values_web(output);
#endif
#ifdef EMSESP_USE_SERIAL
#ifdef EMSESP_DEBUG
serializeJson(output, Serial);
#endif
#endif
response->setLength();
request->send(response);
@@ -246,7 +257,7 @@ void WebDataService::write_sensor(AsyncWebServerRequest * request, JsonVariant &
if (json.is<JsonObject>()) {
JsonObject sensor = json;
std::string id_str = sensor["id_str"]; // this is the key
std::string id = sensor["id"]; // this is the key
std::string name = sensor["name"];
// calculate offset. We'll convert it to an int and * 10
@@ -255,7 +266,7 @@ void WebDataService::write_sensor(AsyncWebServerRequest * request, JsonVariant &
if (EMSESP::system_.fahrenheit()) {
offset10 = offset / 0.18;
}
ok = EMSESP::dallassensor_.update(id_str, name, offset10);
ok = EMSESP::dallassensor_.update(id, name, offset10);
}
AsyncWebServerResponse * response = request->beginResponse(ok ? 200 : 204);
@@ -268,13 +279,13 @@ void WebDataService::write_analog(AsyncWebServerRequest * request, JsonVariant &
if (json.is<JsonObject>()) {
JsonObject analog = json;
uint8_t id = analog["id"]; // this is the unique key
uint8_t gpio = analog["gpio"]; // this is the unique key, the GPIO
std::string name = analog["name"];
float factor = analog["factor"];
float offset = analog["offset"];
uint8_t uom = analog["uom"];
int8_t type = analog["type"];
ok = EMSESP::analogsensor_.update(id, name, offset, factor, uom, type);
ok = EMSESP::analogsensor_.update(gpio, name, offset, factor, uom, type);
}
AsyncWebServerResponse * response = request->beginResponse(ok ? 200 : 204);