Fork of the espurna firmware for `mhsw` switches
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/*
BUTTON MODULE
Copyright (C) 2016-2019 by Xose Pérez <xose dot perez at gmail dot com>
*/
#include "button.h"
#if BUTTON_SUPPORT
#include <bitset>
#include <memory>
#include <vector>
#include "compat.h"
#include "gpio.h"
#include "system.h"
#include "mqtt.h"
#include "relay.h"
#include "light.h"
#include "ws.h"
#include "libs/BasePin.h"
#include "libs/DebounceEvent.h"
#include "gpio_pin.h"
#include "mcp23s08_pin.h"
#include "button_config.h"
BrokerBind(ButtonBroker);
// TODO: if we are using such conversion helpers across the codebase, should convert() be in internal ns?
namespace settings {
namespace internal {
template<>
debounce_event::types::Mode convert(const String& value) {
switch (value.toInt()) {
case 1:
return debounce_event::types::Mode::Switch;
case 0:
default:
return debounce_event::types::Mode::Pushbutton;
}
}
template<>
String serialize(const debounce_event::types::Mode& value) {
String result;
switch (value) {
case debounce_event::types::Mode::Switch:
result = "1";
break;
case debounce_event::types::Mode::Pushbutton:
default:
result = "0";
break;
}
return result;
}
template<>
debounce_event::types::PinValue convert(const String& value) {
switch (value.toInt()) {
case 0:
return debounce_event::types::PinValue::Low;
case 1:
default:
return debounce_event::types::PinValue::High;
}
}
template<>
String serialize(const debounce_event::types::PinValue& value) {
String result;
switch (value) {
case debounce_event::types::PinValue::Low:
result = "0";
break;
case debounce_event::types::PinValue::High:
default:
result = "1";
break;
}
return result;
}
template<>
debounce_event::types::PinMode convert(const String& value) {
switch (value.toInt()) {
case 1:
return debounce_event::types::PinMode::InputPullup;
case 2:
return debounce_event::types::PinMode::InputPulldown;
case 0:
default:
return debounce_event::types::PinMode::Input;
}
}
template<>
String serialize(const debounce_event::types::PinMode& mode) {
String result;
switch (mode) {
case debounce_event::types::PinMode::InputPullup:
result = "1";
break;
case debounce_event::types::PinMode::InputPulldown:
result = "2";
break;
case debounce_event::types::PinMode::Input:
default:
result = "0";
break;
}
return result;
}
} // namespace settings::internal
} // namespace settings
// -----------------------------------------------------------------------------
constexpr const debounce_event::types::Config _buttonDecodeConfigBitmask(const unsigned char bitmask) {
return {
((bitmask & ButtonMask::Pushbutton)
? debounce_event::types::Mode::Pushbutton
: debounce_event::types::Mode::Switch),
((bitmask & ButtonMask::DefaultHigh)
? debounce_event::types::PinValue::High
: debounce_event::types::PinValue::Low),
((bitmask & ButtonMask::SetPullup) ? debounce_event::types::PinMode::InputPullup
: (bitmask & ButtonMask::SetPulldown) ? debounce_event::types::PinMode::InputPulldown
: debounce_event::types::PinMode::Input)
};
}
constexpr const button_action_t _buttonDecodeEventAction(const button_actions_t& actions, button_event_t event) {
return (
(event == button_event_t::Pressed) ? actions.pressed :
(event == button_event_t::Released) ? actions.released :
(event == button_event_t::Click) ? actions.click :
(event == button_event_t::DoubleClick) ? actions.dblclick :
(event == button_event_t::LongClick) ? actions.lngclick :
(event == button_event_t::LongLongClick) ? actions.lnglngclick :
(event == button_event_t::TripleClick) ? actions.trplclick : 0U
);
}
constexpr const button_event_t _buttonMapReleased(uint8_t count, unsigned long length, unsigned long lngclick_delay, unsigned long lnglngclick_delay) {
return (
(0 == count) ? button_event_t::Released :
(1 == count) ? (
(length > lnglngclick_delay) ? button_event_t::LongLongClick :
(length > lngclick_delay) ? button_event_t::LongClick : button_event_t::Click
) :
(2 == count) ? button_event_t::DoubleClick :
(3 == count) ? button_event_t::TripleClick :
button_event_t::None
);
}
button_actions_t _buttonConstructActions(unsigned char index) {
return {
_buttonPress(index),
_buttonRelease(index),
_buttonClick(index),
_buttonDoubleClick(index),
_buttonLongClick(index),
_buttonLongLongClick(index),
_buttonTripleClick(index)
};
}
debounce_event::types::Config _buttonRuntimeConfig(unsigned char index) {
const auto config = _buttonDecodeConfigBitmask(_buttonConfigBitmask(index));
return {
getSetting({"btnMode", index}, config.mode),
getSetting({"btnDefVal", index}, config.default_value),
getSetting({"btnPinMode", index}, config.pin_mode)
};
}
int _buttonEventNumber(button_event_t event) {
return static_cast<int>(event);
}
// -----------------------------------------------------------------------------
button_event_delays_t::button_event_delays_t() :
debounce(_buttonDebounceDelay()),
repeat(_buttonRepeatDelay()),
lngclick(_buttonLongClickDelay()),
lnglngclick(_buttonLongLongClickDelay())
{}
button_event_delays_t::button_event_delays_t(unsigned long debounce, unsigned long repeat, unsigned long lngclick, unsigned long lnglngclick) :
debounce(debounce),
repeat(repeat),
lngclick(lngclick),
lnglngclick(lnglngclick)
{}
button_t::button_t(unsigned char relayID, const button_actions_t& actions, const button_event_delays_t& delays) :
event_emitter(nullptr),
event_delays(delays),
actions(actions),
relayID(relayID)
{}
button_t::button_t(std::shared_ptr<BasePin> pin, const debounce_event::types::Config& config, unsigned char relayID, const button_actions_t& actions, const button_event_delays_t& delays) :
event_emitter(std::make_unique<debounce_event::EventEmitter>(pin, config, delays.debounce, delays.repeat)),
event_delays(delays),
actions(actions),
relayID(relayID)
{}
bool button_t::state() {
return event_emitter->isPressed();
}
button_event_t button_t::loop() {
if (event_emitter) {
switch (event_emitter->loop()) {
case debounce_event::types::EventPressed:
return button_event_t::Pressed;
case debounce_event::types::EventReleased: {
return _buttonMapReleased(
event_emitter->getEventCount(),
event_emitter->getEventLength(),
event_delays.lngclick,
event_delays.lnglngclick
);
}
case debounce_event::types::EventNone:
break;
}
}
return button_event_t::None;
}
std::vector<button_t> _buttons;
// -----------------------------------------------------------------------------
unsigned char buttonCount() {
return _buttons.size();
}
#if MQTT_SUPPORT
std::bitset<ButtonsMax> _buttons_mqtt_send_all(
(1 == BUTTON_MQTT_SEND_ALL_EVENTS) ? 0xFFFFFFFFUL : 0UL
);
std::bitset<ButtonsMax> _buttons_mqtt_retain(
(1 == BUTTON_MQTT_RETAIN) ? 0xFFFFFFFFUL : 0UL
);
#endif
#if WEB_SUPPORT
void _buttonWebSocketOnVisible(JsonObject& root) {
if (buttonCount() > 0) {
root["btnVisible"] = 1;
}
}
void _buttonWebSocketOnConnected(JsonObject& root) {
root["btnRepDel"] = getSetting("btnRepDel", _buttonRepeatDelay());
// XXX: unused! pending webui changes
#if 0
if (buttonCount() < 1) return;
JsonObject& module = root.createNestedObject("btn");
// TODO: hardware can sometimes use a different providers
// e.g. Sonoff Dual does not need `Pin`, `Mode` or any of `Del`
// TODO: schema names are uppercase to easily match settings?
// TODO: schema name->type map to generate WebUI elements?
JsonArray& schema = module.createNestedArray("_schema");
schema.add("Prov");
schema.add("GPIO");
schema.add("Mode");
schema.add("DefVal");
schema.add("PinMode");
schema.add("Press");
schema.add("Click");
schema.add("Dclk");
schema.add("Lclk");
schema.add("LLclk");
schema.add("Tclk");
schema.add("DebDel");
schema.add("RepDel");
schema.add("LclkDel");
schema.add("LLclkDel");
#if RELAY_SUPPORT
schema.add("Relay");
#endif
#if MQTT_SUPPORT
schema.add("MqttSendAll");
schema.add("MqttRetain");
#endif
JsonArray& buttons = module.createNestedArray("list");
for (unsigned char i=0; i<buttonCount(); i++) {
JsonArray& button = buttons.createNestedArray();
// TODO: configure PIN object instead of button specifically, link PIN<->BUTTON
button.add(getSetting({"btnProv", index}, _buttonProvider(index)));
if (_buttons[i].getPin()) {
button.add(getSetting({"btnGPIO", index}, _buttonPin(index)));
const auto config = _buttonRuntimeConfig(index);
button.add(static_cast<int>(config.mode));
button.add(static_cast<int>(config.default_value));
button.add(static_cast<int>(config.pin_mode));
} else {
button.add(GPIO_NONE);
button.add(static_cast<int>(BUTTON_PUSHBUTTON));
button.add(0);
button.add(0);
button.add(0);
}
button.add(_buttons[i].actions.pressed);
button.add(_buttons[i].actions.click);
button.add(_buttons[i].actions.dblclick);
button.add(_buttons[i].actions.lngclick);
button.add(_buttons[i].actions.lnglngclick);
button.add(_buttons[i].actions.trplclick);
button.add(_buttons[i].event_delays.debounce);
button.add(_buttons[i].event_delays.repeat);
button.add(_buttons[i].event_delays.lngclick);
button.add(_buttons[i].event_delays.lnglngclick);
#if RELAY_SUPPORT
button.add(_buttons[i].relayID);
#endif
// TODO: send bitmask as number?
#if MQTT_SUPPORT
button.add(_buttons_mqtt_send_all[i] ? 1 : 0);
button.add(_buttons_mqtt_retain[i] ? 1 : 0);
#endif
}
#endif
}
bool _buttonWebSocketOnKeyCheck(const char * key, JsonVariant&) {
return (strncmp(key, "btn", 3) == 0);
}
#endif // WEB_SUPPORT
bool buttonState(unsigned char id) {
if (id >= _buttons.size()) return false;
return _buttons[id].state();
}
button_action_t buttonAction(unsigned char id, const button_event_t event) {
if (id >= _buttons.size()) return 0;
return _buttonDecodeEventAction(_buttons[id].actions, event);
}
// Note that we don't directly return F(...), but use a temporary to assign it conditionally
// (ref. https://github.com/esp8266/Arduino/pull/6950 "PROGMEM footprint cleanup for responseCodeToString")
// In this particular case, saves 76 bytes (120 vs 44)
String _buttonEventString(button_event_t event) {
const __FlashStringHelper* ptr = nullptr;
switch (event) {
case button_event_t::Pressed:
ptr = F("pressed");
break;
case button_event_t::Released:
ptr = F("released");
break;
case button_event_t::Click:
ptr = F("click");
break;
case button_event_t::DoubleClick:
ptr = F("double-click");
break;
case button_event_t::LongClick:
ptr = F("long-click");
break;
case button_event_t::LongLongClick:
ptr = F("looong-click");
break;
case button_event_t::TripleClick:
ptr = F("triple-click");
break;
case button_event_t::None:
ptr = F("none");
break;
}
return String(ptr);
}
void buttonEvent(unsigned char id, button_event_t event) {
DEBUG_MSG_P(PSTR("[BUTTON] Button #%u event %d (%s)\n"),
id, _buttonEventNumber(event), _buttonEventString(event).c_str()
);
if (event == button_event_t::None) return;
auto& button = _buttons[id];
auto action = _buttonDecodeEventAction(button.actions, event);
#if BROKER_SUPPORT
ButtonBroker::Publish(id, event);
#endif
#if MQTT_SUPPORT
if (action || _buttons_mqtt_send_all[id]) {
mqttSend(MQTT_TOPIC_BUTTON, id, _buttonEventString(event).c_str(), false, _buttons_mqtt_retain[id]);
}
#endif
switch (action) {
#if RELAY_SUPPORT
case BUTTON_ACTION_TOGGLE:
relayToggle(button.relayID);
break;
case BUTTON_ACTION_ON:
relayStatus(button.relayID, true);
break;
case BUTTON_ACTION_OFF:
relayStatus(button.relayID, false);
break;
#endif // RELAY_SUPPORT == 1
case BUTTON_ACTION_AP:
if (wifiState() & WIFI_STATE_AP) {
wifiStartSTA();
} else {
wifiStartAP();
}
break;
case BUTTON_ACTION_RESET:
deferredReset(100, CUSTOM_RESET_HARDWARE);
break;
case BUTTON_ACTION_FACTORY:
DEBUG_MSG_P(PSTR("\n\nFACTORY RESET\n\n"));
resetSettings();
deferredReset(100, CUSTOM_RESET_FACTORY);
break;
#if defined(JUSTWIFI_ENABLE_WPS)
case BUTTON_ACTION_WPS:
wifiStartWPS();
break;
#endif // defined(JUSTWIFI_ENABLE_WPS)
#if defined(JUSTWIFI_ENABLE_SMARTCONFIG)
case BUTTON_ACTION_SMART_CONFIG:
wifiStartSmartConfig();
break;
#endif // defined(JUSTWIFI_ENABLE_SMARTCONFIG)
#if LIGHT_PROVIDER != LIGHT_PROVIDER_NONE
case BUTTON_ACTION_DIM_UP:
lightBrightnessStep(1);
lightUpdate(true, true);
break;
case BUTTON_ACTION_DIM_DOWN:
lightBrightnessStep(-1);
lightUpdate(true, true);
break;
#endif // LIGHT_PROVIDER != LIGHT_PROVIDER_NONE
#if THERMOSTAT_DISPLAY_SUPPORT
case BUTTON_ACTION_DISPLAY_ON:
displayOn();
break;
#endif
}
}
void _buttonConfigure() {
#if MQTT_SUPPORT
for (unsigned char index = 0; index < _buttons.size(); ++index) {
_buttons_mqtt_send_all[index] = getSetting({"btnMqttSendAll", index}, _buttonMqttSendAllEvents(index));
_buttons_mqtt_retain[index] = getSetting({"btnMqttRetain", index}, _buttonMqttRetain(index));
}
#endif
}
// TODO: compatibility proxy, fetch global key before indexed
template<typename T>
unsigned long _buttonGetSetting(const char* key, unsigned char index, T default_value) {
return getSetting({key, index}, getSetting(key, default_value));
}
// Sonoff Dual does not do real GPIO readings and we
// depend on the external MCU to send us relay / button events
// Lightfox uses the same protocol as Dual, but has slightly different actions
// TODO: move this to a separate 'hardware' setup file?
void _buttonLoopSonoffDual() {
if (Serial.available() < 4) {
return;
}
unsigned char bytes[4] = {0};
Serial.readBytes(bytes, 4);
if ((bytes[0] != 0xA0) && (bytes[1] != 0x04) && (bytes[3] != 0xA1)) {
return;
}
const unsigned char value [[gnu::unused]] = bytes[2];
#if BUTTON_PROVIDER_ITEAD_SONOFF_DUAL_SUPPORT
// RELAYs and BUTTONs are synchonized in the SIL F330
// The on-board BUTTON2 should toggle RELAY0 value
// Since we are not passing back RELAY2 value
// (in the relayStatus method) it will only be present
// here if it has actually been pressed
if ((value & 4) == 4) {
buttonEvent(2, button_event_t::Click);
return;
}
// Otherwise check if any of the other two BUTTONs
// (in the header) has been pressed, but we should
// ensure that we only toggle one of them to avoid
// the synchronization going mad
// This loop is generic for any PSB-04 module
for (unsigned int i=0; i<relayCount(); i++) {
const bool status = (value & (1 << i)) > 0;
// Check if the status for that relay has changed
if (relayStatus(i) != status) {
buttonEvent(i, button_event_t::Click);
break;
}
}
#elif BUTTON_PROVIDER_FOXEL_LIGHTFOX_DUAL_SUPPORT
DEBUG_MSG_P(PSTR("[BUTTON] [LIGHTFOX] Received buttons mask: %u\n"), value);
for (unsigned int i=0; i<_buttons.size(); i++) {
if ((value & (1 << i)) > 0) {
buttonEvent(i, button_event_t::Click);
}
}
#endif // BUTTON_PROVIDER_ITEAD_SONOFF_DUAL
}
void _buttonLoopGeneric() {
for (size_t id = 0; id < _buttons.size(); ++id) {
auto event = _buttons[id].loop();
if (event != button_event_t::None) {
buttonEvent(id, event);
}
}
}
void buttonLoop() {
_buttonLoopGeneric();
// Unconditionally call these. By default, generic loop will discard everything without the configured events emmiter
#if BUTTON_PROVIDER_ITEAD_SONOFF_DUAL_SUPPORT || BUTTON_PROVIDER_FOXEL_LIGHTFOX_DUAL
_buttonLoopSonoffDual();
#endif
}
// Resistor ladder buttons. Inspired by:
// - https://gitter.im/tinkerman-cat/espurna?at=5f5d44c8df4af236f902e25d
// - https://github.com/bxparks/AceButton/tree/develop/docs/resistor_ladder (especially thx @bxparks for the great documentation!)
// - https://github.com/bxparks/AceButton/blob/develop/src/ace_button/LadderButtonConfig.cpp
// - https://github.com/dxinteractive/AnalogMultiButton
#if BUTTON_PROVIDER_ANALOG_SUPPORT
class AnalogPin final : public BasePin {
public:
static constexpr int RangeFrom { 0 };
static constexpr int RangeTo { 1023 };
AnalogPin() = delete;
AnalogPin(unsigned char) = delete;
AnalogPin(unsigned char pin_, int expected_) :
BasePin(pin_),
_expected(expected_)
{
pins.reserve(ButtonsPresetMax);
pins.push_back(this);
adjustPinRanges();
}
~AnalogPin() {
pins.erase(std::remove(pins.begin(), pins.end(), this), pins.end());
adjustPinRanges();
}
// Notice that 'static' method vars are shared between instances
// This way we will throttle every invocation (which should be safe to do, since we only read things through the button loop)
int analogRead() {
static unsigned long ts { ESP.getCycleCount() };
static int last { ::analogRead(pin) };
// Cannot hammer analogRead() all the time:
// https://github.com/esp8266/Arduino/issues/1634
if (ESP.getCycleCount() - ts >= _read_interval) {
ts = ESP.getCycleCount();
last = ::analogRead(pin);
}
return last;
}
// XXX: make static ctor and call this implicitly?
static bool checkExpectedLevel(int expected) {
if (expected > RangeTo) {
return false;
}
for (auto pin : pins) {
if (expected == pin->_expected) {
return false;
}
}
return true;
}
String description() const override {
char buffer[64] {0};
snprintf_P(buffer, sizeof(buffer),
PSTR("AnalogPin @ GPIO%u, expected %d (%d, %d)"),
pin, _expected, _from, _to
);
return String(buffer);
}
// Simulate LOW level when the range matches and HIGH when it does not
int digitalRead() override {
const auto reading = analogRead();
return !((_from < reading) && (reading < _to));
}
void pinMode(int8_t) override {
}
void digitalWrite(int8_t val) override {
}
private:
// ref. https://github.com/bxparks/AceButton/tree/develop/docs/resistor_ladder#level-matching-tolerance-range
// fuzzy matching instead of directly comparing with the `_expected` level and / or specifying tolerance manually
// for example, for pins with expected values 0, 327, 512 and 844 we match analogRead() when:
// - 0..163 for 0
// - 163..419 for 327
// - 419..678 for 512
// - 678..933 for 844
// - 933..1024 is ignored
static std::vector<AnalogPin*> pins;
unsigned long _read_interval { microsecondsToClockCycles(200u) };
int _expected { 0u };
int _from { RangeFrom };
int _to { RangeTo };
static void adjustPinRanges() {
std::sort(pins.begin(), pins.end(), [](const AnalogPin* lhs, const AnalogPin* rhs) -> bool {
return lhs->_expected < rhs->_expected;
});
AnalogPin* last { nullptr };
for (unsigned index = 0; index < pins.size(); ++index) {
int edge = (index + 1 != pins.size())
? pins[index + 1]->_expected
: RangeTo;
pins[index]->_from = last
? last->_to
: RangeFrom;
pins[index]->_to = (pins[index]->_expected + edge) / 2;
last = pins[index];
}
}
};
std::vector<AnalogPin*> AnalogPin::pins;
#endif // BUTTON_PROVIDER_ANALOG_SUPPORT
std::shared_ptr<BasePin> _buttonFromProvider([[gnu::unused]] unsigned char index, int provider, unsigned char pin) {
switch (provider) {
case BUTTON_PROVIDER_GENERIC:
if (!gpioValid(pin)) {
break;
}
return std::shared_ptr<BasePin>(new GpioPin(pin));
#if BUTTON_PROVIDER_MCP23S08_SUPPORT
case BUTTON_PROVIDER_MCP23S08:
if (!mcpGpioValid(pin)) {
break;
}
return std::shared_ptr<BasePin>(new McpGpioPin(pin));
#endif
#if BUTTON_PROVIDER_ANALOG_SUPPORT
case BUTTON_PROVIDER_ANALOG: {
if (A0 != pin) {
break;
}
const auto level = getSetting({"btnLevel", index}, _buttonAnalogLevel(index));
if (!AnalogPin::checkExpectedLevel(level)) {
break;
}
return std::shared_ptr<BasePin>(new AnalogPin(pin, level));
}
#endif
default:
break;
}
return {};
}
void buttonSetup() {
// Backwards compatibility
moveSetting("btnDelay", "btnRepDel");
// Special hardware cases
#if BUTTON_PROVIDER_ITEAD_SONOFF_DUAL_SUPPORT || BUTTON_PROVIDER_FOXEL_LIGHTFOX_DUAL
{
size_t buttons = 0;
#if BUTTON1_RELAY != RELAY_NONE
++buttons;
#endif
#if BUTTON2_RELAY != RELAY_NONE
++buttons;
#endif
#if BUTTON3_RELAY != RELAY_NONE
++buttons;
#endif
#if BUTTON4_RELAY != RELAY_NONE
++buttons;
#endif
_buttons.reserve(buttons);
// Ignore real button delays since we don't use them here
const auto delays = button_event_delays_t();
for (unsigned char index = 0; index < buttons; ++index) {
const button_actions_t actions {
BUTTON_ACTION_NONE,
BUTTON_ACTION_NONE,
// The only generated event is ::Click
getSetting({"btnClick", index}, _buttonClick(index)),
BUTTON_ACTION_NONE,
BUTTON_ACTION_NONE,
BUTTON_ACTION_NONE,
BUTTON_ACTION_NONE
};
_buttons.emplace_back(
getSetting({"btnRelay", index}, _buttonRelay(index)),
actions,
delays
);
}
}
#endif // BUTTON_PROVIDER_ITEAD_SONOFF_DUAL_SUPPORT || BUTTON_PROVIDER_FOXEL_LIGHTFOX_DUAL
#if BUTTON_PROVIDER_GENERIC_SUPPORT
// Generic GPIO input handlers
{
_buttons.reserve(_buttonPreconfiguredPins());
for (unsigned char index = _buttons.size(); index < ButtonsMax; ++index) {
const auto provider = getSetting({"btnProv", index}, _buttonProvider(index));
const auto pin = getSetting({"btnGPIO", index}, _buttonPin(index));
auto managed_pin = _buttonFromProvider(index, provider, pin);
if (!managed_pin) {
break;
}
const auto relayID = getSetting({"btnRelay", index}, _buttonRelay(index));
// TODO: compatibility proxy, fetch global key before indexed
const button_event_delays_t delays {
_buttonGetSetting("btnDebDel", index, _buttonDebounceDelay(index)),
_buttonGetSetting("btnRepDel", index, _buttonRepeatDelay(index)),
_buttonGetSetting("btnLclkDel", index, _buttonLongClickDelay(index)),
_buttonGetSetting("btnLLclkDel", index, _buttonLongLongClickDelay(index)),
};
const button_actions_t actions {
getSetting({"btnPress", index}, _buttonPress(index)),
getSetting({"btnRlse", index}, _buttonRelease(index)),
getSetting({"btnClick", index}, _buttonClick(index)),
getSetting({"btnDclk", index}, _buttonDoubleClick(index)),
getSetting({"btnLclk", index}, _buttonLongClick(index)),
getSetting({"btnLLclk", index}, _buttonLongLongClick(index)),
getSetting({"btnTclk", index}, _buttonTripleClick(index))
};
const auto config = _buttonRuntimeConfig(index);
_buttons.emplace_back(
managed_pin, config,
relayID, actions, delays
);
}
}
#endif
#if TERMINAL_SUPPORT
if (_buttons.size()) {
terminalRegisterCommand(F("BUTTON"), [](const terminal::CommandContext& ctx) {
unsigned index { 0u };
for (auto& button : _buttons) {
ctx.output.printf("%u - ", index++);
if (button.event_emitter) {
auto pin = button.event_emitter->getPin();
ctx.output.println(pin->description());
} else {
ctx.output.println(F("Virtual"));
}
}
terminalOK(ctx);
});
}
#endif
_buttonConfigure();
DEBUG_MSG_P(PSTR("[BUTTON] Number of buttons: %u\n"), _buttons.size());
// Websocket Callbacks
#if WEB_SUPPORT
wsRegister()
.onConnected(_buttonWebSocketOnVisible)
.onVisible(_buttonWebSocketOnVisible)
.onKeyCheck(_buttonWebSocketOnKeyCheck);
#endif
// Register system callbacks
espurnaRegisterLoop(buttonLoop);
espurnaRegisterReload(_buttonConfigure);
}
#endif // BUTTON_SUPPORT