/* RELAY MODULE Copyright (C) 2016-2019 by Xose Pérez */ #include "relay.h" #if RELAY_SUPPORT #include #include #include #include #include #include "api.h" #include "broker.h" #include "mqtt.h" #include "rpc.h" #include "rtcmem.h" #include "settings.h" #include "storage_eeprom.h" #include "utils.h" #include "ws.h" #include "libs/BasePin.h" #include "relay_config.h" // Relay statuses are kept in a mutable bitmask struct // TODO: u32toString should be convert(...) ? namespace { String u32toString(uint32_t value, int base) { String result; result.reserve(32 + 2); if (base == 2) { result += "0b"; } else if (base == 8) { result += "0o"; } else if (base == 16) { result += "0x"; } char buffer[33] = {0}; ultoa(value, buffer, base); result += buffer; return result; } using RelayMask = std::bitset; struct RelayMaskHelper { RelayMaskHelper() = default; explicit RelayMaskHelper(uint32_t mask) : _mask(mask) {} explicit RelayMaskHelper(RelayMask&& mask) : _mask(std::move(mask)) {} uint32_t toUnsigned() const { return _mask.to_ulong(); } String toString() const { return u32toString(toUnsigned(), 2); } const RelayMask& mask() const { return _mask; } void reset() { _mask.reset(); } void set(unsigned char id, bool status) { _mask.set(id, status); } bool operator[](size_t id) const { return _mask[id]; } private: RelayMask _mask { 0ul }; }; } // namespace template T _relayPayloadToTristate(const char* payload) { auto len = strlen(payload); if (len == 1) { switch (payload[0]) { case '0': return T::None; case '1': return T::Off; case '2': return T::On; } } else if (len > 1) { String cmp(payload); if (cmp == "none") { return T::None; } else if (cmp == "off") { return T::Off; } else if (cmp == "on") { return T::On; } } return T::None; } template const char* _relayTristateToPayload(T tristate) { static_assert(std::is_enum::value, ""); switch (tristate) { case T::Off: return "off"; case T::On: return "on"; case T::None: break; } return "none"; } const char* _relayPulseToPayload(RelayPulse pulse) { return _relayTristateToPayload(pulse); } const char* _relayLockToPayload(RelayLock lock) { return _relayTristateToPayload(lock); } namespace settings { namespace internal { template <> PayloadStatus convert(const String& value) { auto status = static_cast(value.toInt()); switch (status) { case PayloadStatus::Off: case PayloadStatus::On: case PayloadStatus::Toggle: case PayloadStatus::Unknown: return status; } return PayloadStatus::Unknown; } template <> RelayMqttTopicMode convert(const String& value) { auto mode = static_cast(value.toInt()); switch (mode) { case RelayMqttTopicMode::Normal: case RelayMqttTopicMode::Inverse: return mode; } return RelayMqttTopicMode::Normal; } template <> RelayPulse convert(const String& value) { return _relayPayloadToTristate(value.c_str()); } template <> RelayLock convert(const String& value) { return _relayPayloadToTristate(value.c_str()); } template <> RelayProvider convert(const String& value) { auto type = static_cast(value.toInt()); switch (type) { case RelayProvider::None: case RelayProvider::Dummy: case RelayProvider::Gpio: case RelayProvider::Dual: case RelayProvider::Stm: return type; } return RelayProvider::None; } template <> RelayType convert(const String& value) { auto type = static_cast(value.toInt()); switch (type) { case RelayType::Normal: case RelayType::Inverse: case RelayType::Latched: case RelayType::LatchedInverse: return type; } return RelayType::Normal; } template <> RelayMaskHelper convert(const String& value) { return RelayMaskHelper(convert(value)); } template <> String serialize(const RelayMaskHelper& mask) { return mask.toString(); } } // namespace internal } // namespace settings // ----------------------------------------------------------------------------- // RELAY CONTROL // ----------------------------------------------------------------------------- RelayProviderBase* _relayDummyProvider(); struct relay_t { public: // Struct defaults to empty relay configuration, as we allow switches to exist without real GPIOs relay_t() = default; relay_t(RelayProviderBasePtr&& provider_) : provider(provider_.release()) {} relay_t(RelayProviderBase* provider_) : provider(provider_) {} // ON / OFF actions implementation RelayProviderBase* provider { _relayDummyProvider() }; // Timers unsigned long delay_on { 0ul }; // Delay to turn relay ON unsigned long delay_off { 0ul }; // Delay to turn relay OFF RelayPulse pulse { RelayPulse::None }; // Sets up a timer for the opposite mode unsigned long pulse_ms { 0ul }; // Pulse length in millis Ticker* pulseTicker { nullptr }; // Holds the pulse back timer unsigned long fw_start { 0ul }; // Flood window start time unsigned char fw_count { 0u }; // Number of changes within the current flood window unsigned long change_start { 0ul }; // Time when relay was scheduled to change unsigned long change_delay { 0ul }; // Delay until the next change // Status bool current_status { false }; // Holds the current (physical) status of the relay bool target_status { false }; // Holds the target status RelayLock lock { RelayLock::None }; // Holds the value of target status that persists and cannot be changed from. // MQTT bool report { false }; // Whether to report to own topic bool group_report { false }; // Whether to report to group topic }; std::vector _relays; bool _relayRecursive = false; size_t _relayDummy = 0; unsigned long _relay_flood_window = (1000 * RELAY_FLOOD_WINDOW); unsigned long _relay_flood_changes = RELAY_FLOOD_CHANGES; unsigned long _relay_delay_interlock; unsigned char _relay_sync_mode = RELAY_SYNC_ANY; bool _relay_sync_locked = false; Ticker _relay_save_timer; Ticker _relay_sync_timer; RelayStatusCallback _relay_status_notify { nullptr }; RelayStatusCallback _relay_status_change { nullptr }; #if WEB_SUPPORT bool _relay_report_ws = false; void _relayWsReport() { _relay_report_ws = true; } #endif // WEB_SUPPORT #if MQTT_SUPPORT || API_SUPPORT String _relay_rpc_payload_on; String _relay_rpc_payload_off; String _relay_rpc_payload_toggle; #endif // MQTT_SUPPORT || API_SUPPORT // ----------------------------------------------------------------------------- // RELAY PROVIDERS // ----------------------------------------------------------------------------- // 'anchor' default virtual implementations to the relay.cpp.o RelayProviderBase::~RelayProviderBase() { } void RelayProviderBase::dump() { } bool RelayProviderBase::setup() { return true; } void RelayProviderBase::boot(bool) { } void RelayProviderBase::notify(bool) { } // Direct status notifications void relaySetStatusNotify(RelayStatusCallback callback) { _relay_status_notify = callback; } void relaySetStatusChange(RelayStatusCallback callback) { _relay_status_change = callback; } // No-op provider, available for purely virtual relays that are controlled only via API struct DummyProvider : public RelayProviderBase { const char* id() const override { return "dummy"; } void change(bool) override { } }; RelayProviderBase* _relayDummyProvider() { static DummyProvider provider; return &provider; } // Real GPIO provider, using BasePin interface to implement writers struct GpioProvider : public RelayProviderBase { GpioProvider(unsigned char id, RelayType type, std::unique_ptr&& pin, std::unique_ptr&& reset_pin) : _id(id), _type(type), _pin(std::move(pin)), _reset_pin(std::move(reset_pin)) {} const char* id() const override { return "gpio"; } bool setup() override { if (!_pin) { return false; } _pin->pinMode(OUTPUT); if (_reset_pin) { _reset_pin->pinMode(OUTPUT); } if (_type == RelayType::Inverse) { _pin->digitalWrite(HIGH); } return true; } void change(bool status) override { switch (_type) { case RelayType::Normal: _pin->digitalWrite(status); break; case RelayType::Inverse: _pin->digitalWrite(!status); break; case RelayType::Latched: case RelayType::LatchedInverse: { bool pulse = (_type == RelayType::Latched) ? HIGH : LOW; _pin->digitalWrite(!pulse); if (_reset_pin) { _reset_pin->digitalWrite(!pulse); } if (status || (!_reset_pin)) { _pin->digitalWrite(pulse); } else { _reset_pin->digitalWrite(pulse); } nice_delay(RELAY_LATCHING_PULSE); // TODO: note that we stall loop() execution // need to ensure only relay task is active _pin->digitalWrite(!pulse); if (_reset_pin) { _reset_pin->digitalWrite(!pulse); } } } } private: unsigned char _id { RELAY_NONE }; RelayType _type { RelayType::Normal }; std::unique_ptr _pin; std::unique_ptr _reset_pin; }; // Special provider for Sonoff Dual, using serial protocol #if RELAY_PROVIDER_DUAL_SUPPORT class DualProvider : public RelayProviderBase { public: DualProvider() = delete; explicit DualProvider(unsigned char id) : _id(id) { _instances.push_back(this); } ~DualProvider() { _instances.erase( std::remove(_instances.begin(), _instances.end(), this), _instances.end()); } const char* id() const override { return "dual"; } bool setup() override { static bool once { false }; if (!once) { once = true; Serial.begin(SERIAL_BAUDRATE); espurnaRegisterLoop(loop); } return true; } void change(bool) override { static bool scheduled { false }; if (!scheduled) { schedule_function([]() { flush(); scheduled = false; }); } } unsigned char relayId() const { return _id; } static std::vector& instances() { return _instances; } // Porting the old masking code from buttons // (no guarantee that this actually works, based on hearsay and some 3rd-party code) // | first | second | mask | // | OFF | OFF | 0x0 | // | ON | OFF | 0x1 | // | OFF | ON | 0x2 | // | ON | ON | 0x3 | // i.e. set status bit mask[INSTANCE] for each relay // unless everything is ON, then *only* send mask[SIZE] bit and erase the rest static void flush() { bool sync { true }; RelayMaskHelper mask; for (unsigned char index = 0; index < _instances.size(); ++index) { bool status { relayStatus(_instances[index]->relayId()) }; sync = sync && status; mask.set(index, status); } if (sync) { mask.reset(); mask.set(_instances.size(), true); } DEBUG_MSG_P(PSTR("[RELAY] Sending DUAL mask: %s\n"), mask.toString().c_str()); uint8_t buffer[4] { 0xa0, 0x04, static_cast(mask.toUnsigned()), 0xa1 }; Serial.write(buffer, sizeof(buffer)); Serial.flush(); } static void loop() { 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; } // RELAYs and BUTTONs are synchonized in the SIL F330 // Make sure we handle SYNC action first RelayMaskHelper mask(bytes[2]); if (mask[_instances.size()]) { for (auto& instance : _instances) { relayStatus(instance->relayId(), true); } return; } // Then, manage relays individually for (unsigned char index = 0; index < _instances.size(); ++index) { relayStatus(_instances[index]->relayId(), mask[index]); } } private: unsigned char _id { 0 }; static std::vector _instances; }; std::vector DualProvider::_instances; #endif // RELAY_PROVIDER_DUAL_SUPPORT // Special provider for ESP01-relays with STM co-MCU driving the relays #if RELAY_PROVIDER_STM_SUPPORT class StmProvider : public RelayProviderBase { public: StmProvider() = delete; explicit StmProvider(unsigned char id) : _id(id) {} const char* id() const override { return "stm"; } bool setup() override { static bool once { false }; if (!once) { once = true; Serial.begin(SERIAL_BAUDRATE); } return true; } void boot(bool) override { // XXX: this was part of the legacy implementation // "because of broken stm relay firmware" _relays[_id].change_delay = 3000 + 1000 * _id; } void change(bool status) { Serial.flush(); Serial.write(0xA0); Serial.write(_id + 1); Serial.write(status); Serial.write(0xA1 + status + _id); // TODO: is this really solved via interlock delay, so we don't have to switch contexts here? //delay(100); Serial.flush(); } private: unsigned char _id; }; #endif // RELAY_PROVIDER_STM_SUPPORT // ----------------------------------------------------------------------------- // UTILITY // ----------------------------------------------------------------------------- bool _relayTryParseId(const char* p, unsigned char& relayID) { char* endp { nullptr }; const unsigned long result { strtoul(p, &endp, 10) }; if ((endp == p) || (*endp != '\0') || (result >= relayCount())) { return false; } relayID = result; return true; } bool _relayTryParseIdFromPath(const String& endpoint, unsigned char& relayID) { int next_slash { endpoint.lastIndexOf('/') }; if (next_slash < 0) { return false; } const char* p { endpoint.c_str() + next_slash + 1 }; if (*p == '\0') { DEBUG_MSG_P(PSTR("[RELAY] relayID was not specified\n")); return false; } return _relayTryParseId(p, relayID); } void _relayHandleStatus(unsigned char relayID, PayloadStatus status) { switch (status) { case PayloadStatus::Off: relayStatus(relayID, false); break; case PayloadStatus::On: relayStatus(relayID, true); break; case PayloadStatus::Toggle: relayToggle(relayID); break; case PayloadStatus::Unknown: break; } } bool _relayHandlePayload(unsigned char relayID, const char* payload) { auto status = relayParsePayload(payload); if (status != PayloadStatus::Unknown) { _relayHandleStatus(relayID, status); return true; } DEBUG_MSG_P(PSTR("[RELAY] Invalid API payload (%s)\n"), payload); return false; } bool _relayHandlePayload(unsigned char relayID, const String& payload) { return _relayHandlePayload(relayID, payload.c_str()); } bool _relayHandlePulsePayload(unsigned char id, const char* payload) { unsigned long pulse = 1000 * atof(payload); if (!pulse) { return false; } if (RelayPulse::None != _relays[id].pulse) { DEBUG_MSG_P(PSTR("[RELAY] Overriding relayID %u pulse settings\n"), id); } _relays[id].pulse_ms = pulse; _relays[id].pulse = relayStatus(id) ? RelayPulse::On : RelayPulse::Off; relayToggle(id, true, false); return true; } bool _relayHandlePulsePayload(unsigned char id, const String& payload) { return _relayHandlePulsePayload(id, payload.c_str()); } PayloadStatus _relayInvertStatus(PayloadStatus status) { switch (status) { case PayloadStatus::On: return PayloadStatus::Off; case PayloadStatus::Off: return PayloadStatus::On; case PayloadStatus::Toggle: case PayloadStatus::Unknown: break; } return PayloadStatus::Unknown; } PayloadStatus _relayPayloadStatus(unsigned char id) { if (id < _relays.size()) { return _relays[id].current_status ? PayloadStatus::On : PayloadStatus::Off; } return PayloadStatus::Unknown; } void _relayLockAll() { for (auto& relay : _relays) { relay.lock = relay.target_status ? RelayLock::On : RelayLock::Off; } _relay_sync_locked = true; } void _relayUnlockAll() { for (auto& relay : _relays) { relay.lock = RelayLock::None; } _relay_sync_locked = false; } bool _relayStatusLock(unsigned char id, bool status) { if (_relays[id].lock != RelayLock::None) { bool lock = _relays[id].lock == RelayLock::On; if ((lock != status) || (lock != _relays[id].target_status)) { _relays[id].target_status = lock; _relays[id].change_delay = 0; return false; } } return true; } // https://github.com/xoseperez/espurna/issues/1510#issuecomment-461894516 // completely reset timing on the other relay to sync with this one // to ensure that they change state sequentially void _relaySyncRelaysDelay(unsigned char first, unsigned char second) { _relays[second].fw_start = _relays[first].change_start; _relays[second].fw_count = 1; _relays[second].change_delay = std::max({ _relay_delay_interlock, _relays[first].change_delay, _relays[second].change_delay }); } void _relaySyncUnlock() { bool unlock = true; bool all_off = true; for (const auto& relay : _relays) { unlock = unlock && (relay.current_status == relay.target_status); if (!unlock) break; all_off = all_off && !relay.current_status; } if (!unlock) return; auto action = []() { _relayUnlockAll(); #if WEB_SUPPORT _relayWsReport(); #endif }; if (all_off) { _relay_sync_timer.once_ms(_relay_delay_interlock, action); } else { action(); } } // ----------------------------------------------------------------------------- // RELAY // ----------------------------------------------------------------------------- namespace { inline RelayMaskHelper _relayMaskRtcmem() { return RelayMaskHelper(Rtcmem->relay); } inline void _relayMaskRtcmem(uint32_t mask) { Rtcmem->relay = mask; } inline void _relayMaskRtcmem(const RelayMask& mask) { _relayMaskRtcmem(mask.to_ulong()); } inline void _relayMaskRtcmem(const RelayMaskHelper& mask) { _relayMaskRtcmem(mask.toUnsigned()); } RelayMaskHelper _relayMaskSettings() { static RelayMaskHelper defaultMask; return getSetting("relayBootMask", defaultMask); } void _relayMaskSettings(const String& mask) { setSetting("relayBootMask", mask); } inline void _relayMaskSettings(const RelayMaskHelper& mask) { _relayMaskSettings(settings::internal::serialize(mask)); } } // namespace // Pulse timers (timer after ON or OFF event) // TODO: integrate with scheduled ON or OFF void relayPulse(unsigned char id) { auto& relay = _relays[id]; if (!relay.pulseTicker) { relay.pulseTicker = new Ticker(); } relay.pulseTicker->detach(); auto mode = relay.pulse; if (mode == RelayPulse::None) { return; } auto ms = relay.pulse_ms; if (ms == 0) { return; } // TODO: drive ticker on a lower 'tick rate', allow delays longer than 114 minutes // we don't necessarily need millisecond precision. which is also not achievable, most likely, // because of the SDK scheduler. or, at least not for every available provider. // limit is per https://www.espressif.com/sites/default/files/documentation/2c-esp8266_non_os_sdk_api_reference_en.pdf // > 3.1.1 os_timer_arm // > the timer value allowed ranges from 5 to 0x68D7A3. if ((ms < 5) || (ms >= 0x68D7A3)) { DEBUG_MSG_P(PSTR("[RELAY] Unable to schedule the delay %lums (longer than 114 minutes)\n"), ms); return; } if ((mode == RelayPulse::On) != relay.current_status) { DEBUG_MSG_P(PSTR("[RELAY] Scheduling relay #%d back in %lums (pulse)\n"), id, ms); relay.pulseTicker->once_ms(ms, relayToggle, id); // Reconfigure after dynamic pulse relay.pulse = getSetting({"relayPulse", id}, _relayPulseMode(id)); relay.pulse_ms = static_cast(1000.0 * getSetting({"relayTime", id}, _relayPulseTime(id))); } } // General relay status control bool relayStatus(unsigned char id, bool status, bool report, bool group_report) { if (id == RELAY_NONE) return false; if (id >= _relays.size()) return false; if (!_relayStatusLock(id, status)) { DEBUG_MSG_P(PSTR("[RELAY] #%d is locked to %s\n"), id, _relays[id].current_status ? "ON" : "OFF"); _relays[id].report = true; _relays[id].group_report = true; return false; } bool changed = false; if (_relays[id].current_status == status) { if (_relays[id].target_status != status) { DEBUG_MSG_P(PSTR("[RELAY] #%d scheduled change cancelled\n"), id); _relays[id].target_status = status; _relays[id].report = false; _relays[id].group_report = false; _relays[id].change_delay = 0; changed = true; } _relays[id].provider->notify(status); if (_relay_status_notify) { _relay_status_notify(id, status); } // Update the pulse counter if the relay is already in the non-normal state (#454) relayPulse(id); } else { unsigned long current_time = millis(); unsigned long change_delay = status ? _relays[id].delay_on : _relays[id].delay_off; _relays[id].fw_count++; _relays[id].change_start = current_time; _relays[id].change_delay = std::max(_relays[id].change_delay, change_delay); // If current_time is off-limits the floodWindow... const auto fw_diff = current_time - _relays[id].fw_start; if (fw_diff > _relay_flood_window) { // We reset the floodWindow _relays[id].fw_start = current_time; _relays[id].fw_count = 1; // If current_time is in the floodWindow and there have been too many requests... } else if (_relays[id].fw_count >= _relay_flood_changes) { // We schedule the changes to the end of the floodWindow // unless it's already delayed beyond that point _relays[id].change_delay = std::max(change_delay, _relay_flood_window - fw_diff); // Another option is to always move it forward, starting from current time //_relays[id].fw_start = current_time; } _relays[id].target_status = status; _relays[id].report = report; _relays[id].group_report = group_report; relaySync(id); DEBUG_MSG_P(PSTR("[RELAY] #%d scheduled %s in %u ms\n"), id, status ? "ON" : "OFF", _relays[id].change_delay ); changed = true; } return changed; } bool relayStatus(unsigned char id, bool status) { #if MQTT_SUPPORT return relayStatus(id, status, mqttForward(), true); #else return relayStatus(id, status, false, true); #endif } bool relayStatus(unsigned char id) { // Check that relay ID is valid if (id >= _relays.size()) return false; // Get status directly from storage return _relays[id].current_status; } bool relayStatusTarget(unsigned char id) { if (id >= _relays.size()) return false; return _relays[id].target_status; } void relaySync(unsigned char id) { // No sync if none or only one relay if (_relays.size() < 2) return; // Do not go on if we are comming from a previous sync if (_relayRecursive) return; // Flag sync mode _relayRecursive = true; bool status = _relays[id].target_status; // If RELAY_SYNC_SAME all relays should have the same state if (_relay_sync_mode == RELAY_SYNC_SAME) { for (unsigned short i=0; i<_relays.size(); i++) { if (i != id) relayStatus(i, status); } // If RELAY_SYNC_FIRST all relays should have the same state as first if first changes } else if (_relay_sync_mode == RELAY_SYNC_FIRST) { if (id == 0) { for (unsigned short i=1; i<_relays.size(); i++) { relayStatus(i, status); } } } else if ((_relay_sync_mode == RELAY_SYNC_NONE_OR_ONE) || (_relay_sync_mode == RELAY_SYNC_ONE)) { // If NONE_OR_ONE or ONE and setting ON we should set OFF all the others if (status) { if (_relay_sync_mode != RELAY_SYNC_ANY) { for (unsigned short other_id=0; other_id<_relays.size(); other_id++) { if (other_id != id) { relayStatus(other_id, false); if (relayStatus(other_id)) { _relaySyncRelaysDelay(other_id, id); } } } } // If ONLY_ONE and setting OFF we should set ON the other one } else { if (_relay_sync_mode == RELAY_SYNC_ONE) { unsigned char other_id = (id + 1) % _relays.size(); _relaySyncRelaysDelay(id, other_id); relayStatus(other_id, true); } } _relayLockAll(); } // Unflag sync mode _relayRecursive = false; } void relaySave(bool persist) { RelayMaskHelper mask; for (unsigned char id = 0; id < _relays.size(); ++id) { mask.set(id, _relays[id].current_status); } // Persist only to rtcmem, unless requested to save to settings DEBUG_MSG_P(PSTR("[RELAY] Relay mask: %s\n"), mask.toString().c_str()); _relayMaskRtcmem(mask); // The 'persist' flag controls whether we are commiting this change or not. // It is useful to set it to 'false' if the relay change triggering the // save involves a relay whose boot mode is independent from current mode, // thus storing the last relay value is not absolutely necessary. // Nevertheless, we store the value in the EEPROM buffer so it will be written // on the next commit. if (persist) { _relayMaskSettings(mask); eepromCommit(); // TODO: should this respect settings auto-save? } } void relaySave() { relaySave(false); } void relayToggle(unsigned char id, bool report, bool group_report) { if (id >= _relays.size()) return; relayStatus(id, !relayStatus(id), report, group_report); } void relayToggle(unsigned char id) { #if MQTT_SUPPORT relayToggle(id, mqttForward(), true); #else relayToggle(id, false, true); #endif } size_t relayCount() { return _relays.size(); } PayloadStatus relayParsePayload(const char * payload) { #if MQTT_SUPPORT || API_SUPPORT return rpcParsePayload(payload, [](const char* payload) { if (_relay_rpc_payload_off.equals(payload)) { return PayloadStatus::Off; } else if (_relay_rpc_payload_on.equals(payload)) { return PayloadStatus::On; } else if (_relay_rpc_payload_toggle.equals(payload)) { return PayloadStatus::Toggle; } return PayloadStatus::Unknown; }); #else return rpcParsePayload(payload); #endif } void _relaySettingsMigrate(int version) { if (version && (version < 5)) { // just a rename moveSetting("relayDelayInterlock", "relayIlkDelay"); // groups use a new set of keys for (unsigned char index = 0; index < RelaysMax; ++index) { auto group = getSetting({"mqttGroup", index}); if (!group.length()) { break; } auto syncKey = SettingsKey("mqttGroupSync", index); auto sync = getSetting(syncKey); setSetting({"relayTopicSub", index}, group); if (sync.length()) { if (sync != "2") { // aka RECEIVE_ONLY setSetting("relayTopicMode", sync); setSetting("relayTopicPub", group); } } } delSettingPrefix({ "mqttGroup", // migrated to relayTopic "mqttGroupSync", // migrated to relayTopic "relayOnDisc", // replaced with relayMqttDisc "relayGPIO", // avoid depending on migrate.ino "relayProvider", // different type "relayType", // different type }); delSetting("relays"); // does not do anything } } void _relayBoot(unsigned char index, const RelayMaskHelper& mask) { const auto boot_mode = getSetting({"relayBoot", index}, _relayBootMode(index)); auto status = false; auto lock = RelayLock::None; switch (boot_mode) { case RELAY_BOOT_SAME: status = mask[index]; break; case RELAY_BOOT_TOGGLE: status = !mask[index]; break; case RELAY_BOOT_ON: status = true; break; case RELAY_BOOT_LOCKED_ON: status = true; lock = RelayLock::On; break; case RELAY_BOOT_OFF: status = false; break; case RELAY_BOOT_LOCKED_OFF: status = false; lock = RelayLock::Off; break; } auto& relay = _relays[index]; relay.current_status = !status; relay.target_status = status; relay.lock = lock; relay.change_start = millis(); relay.change_delay = status ? relay.delay_on : relay.delay_off; relay.provider->boot(status); } void _relayBootAll() { auto mask = rtcmemStatus() ? _relayMaskRtcmem() : _relayMaskSettings(); _relayRecursive = true; bool once { true }; static RelayMask done; for (unsigned char id = 0; id < relayCount(); ++id) { if (done[id]) { continue; } if (once) { DEBUG_MSG_P(PSTR("[RELAY] Number of relays: %u, boot mask: %s\n"), _relays.size(), mask.toString().c_str()); once = false; } done.set(id, true); _relayBoot(id, mask); } _relayRecursive = false; } void _relayConfigure() { for (unsigned char i = 0, relays = _relays.size() ; (i < relays); ++i) { _relays[i].pulse = getSetting({"relayPulse", i}, _relayPulseMode(i)); _relays[i].pulse_ms = static_cast(1000.0 * getSetting({"relayTime", i}, _relayPulseTime(i))); _relays[i].delay_on = getSetting({"relayDelayOn", i}, _relayDelayOn(i)); _relays[i].delay_off = getSetting({"relayDelayOff", i}, _relayDelayOff(i)); } _relay_flood_window = (1000 * getSetting("relayFloodTime", RELAY_FLOOD_WINDOW)); _relay_flood_changes = getSetting("relayFloodChanges", RELAY_FLOOD_CHANGES); _relay_delay_interlock = getSetting("relayIlkDelay", RELAY_DELAY_INTERLOCK); _relay_sync_mode = getSetting("relaySync", RELAY_SYNC); #if MQTT_SUPPORT || API_SUPPORT settingsProcessConfig({ {_relay_rpc_payload_on, "relayPayloadOn", RELAY_MQTT_ON}, {_relay_rpc_payload_off, "relayPayloadOff", RELAY_MQTT_OFF}, {_relay_rpc_payload_toggle, "relayPayloadToggle", RELAY_MQTT_TOGGLE}, }); #endif // MQTT_SUPPORT } //------------------------------------------------------------------------------ // WEBSOCKETS //------------------------------------------------------------------------------ #if WEB_SUPPORT bool _relayWebSocketOnKeyCheck(const char * key, JsonVariant& value) { return (strncmp(key, "relay", 5) == 0); } void _relayWebSocketUpdate(JsonObject& root) { JsonObject& state = root.createNestedObject("relayState"); state["size"] = relayCount(); JsonArray& status = state.createNestedArray("status"); JsonArray& lock = state.createNestedArray("lock"); // Note: we use byte instead of bool to ever so slightly compress json output for (unsigned char i=0; i(_relays[i].target_status); lock.add(static_cast(_relays[i].lock)); } } void _relayWebSocketRelayConfig(JsonArray& relay, size_t id) { relay.add(static_cast(getSetting({"relayProv", id}, _relayProvider(id)))); relay.add(getSetting({"relayName", id})); relay.add(getSetting({"relayBoot", id}, _relayBootMode(id))); #if MQTT_SUPPORT relay.add(getSetting({"relayTopicSub", id}, _relayMqttTopicSub(id))); relay.add(getSetting({"relayTopicPub", id}, _relayMqttTopicPub(id))); relay.add(static_cast(getSetting({"relayTopicMode", id}, _relayMqttTopicMode(id)))); relay.add(static_cast(getSetting({"relayMqttDisc", id}, _relayMqttDisconnectionStatus(id)))); #endif relay.add(static_cast(_relays[id].pulse)); relay.add(_relays[id].pulse_ms / 1000.0); } void _relayWebSocketSendRelays(JsonObject& root) { if (!relayCount()) { return; } JsonObject& config = root.createNestedObject("relayConfig"); config["size"] = relayCount(); config["start"] = 0; { static constexpr const char* const schema_keys[] PROGMEM = { "relayProv", "relayName", "relayBoot", #if MQTT_SUPPORT "relayTopicPub", "relayTopicSub", "relayTopicMode", "relayMqttDisc", #endif "relayPulse", "relayTime" }; JsonArray& schema = config.createNestedArray("schema"); schema.copyFrom(schema_keys, sizeof(schema_keys) / sizeof(*schema_keys)); } { JsonArray& cfg = config.createNestedArray("cfg"); JsonArray& desc = config.createNestedArray("desc"); for (size_t id = 0; id < relayCount(); ++id) { desc.add(_relays[id].provider->id()); JsonArray& relay = cfg.createNestedArray(); _relayWebSocketRelayConfig(relay, id); } } } void _relayWebSocketOnVisible(JsonObject& root) { if (relayCount() == 0) return; if (relayCount() > 1) { root["multirelayVisible"] = 1; root["relaySync"] = getSetting("relaySync", RELAY_SYNC); root["relayIlkDelay"] = getSetting("relayIlkDelay", RELAY_DELAY_INTERLOCK); } root["relayVisible"] = 1; } void _relayWebSocketOnConnected(JsonObject& root) { _relayWebSocketSendRelays(root); } void _relayWebSocketOnAction(uint32_t client_id, const char * action, JsonObject& data) { if (strcmp(action, "relay") != 0) return; if (data.containsKey("status")) { unsigned int relayID = 0; if (data.containsKey("id") && data.is("id")) { relayID = data["id"]; } _relayHandlePayload(relayID, data["status"].as()); } } void relaySetupWS() { wsRegister() .onVisible(_relayWebSocketOnVisible) .onConnected(_relayWebSocketOnConnected) .onData(_relayWebSocketUpdate) .onAction(_relayWebSocketOnAction) .onKeyCheck(_relayWebSocketOnKeyCheck); } #endif // WEB_SUPPORT //------------------------------------------------------------------------------ // REST API //------------------------------------------------------------------------------ #if API_SUPPORT template bool _relayApiTryHandle(ApiRequest& request, T&& callback) { auto id_param = request.wildcard(0); unsigned char id; if (!_relayTryParseId(id_param.c_str(), id)) { return false; } return callback(id); } void relaySetupAPI() { if (!relayCount()) { return; } apiRegister(F(MQTT_TOPIC_RELAY), [](ApiRequest&, JsonObject& root) { JsonArray& relays = root.createNestedArray("relayStatus"); for (unsigned char id = 0; id < relayCount(); ++id) { relays.add(_relays[id].target_status ? 1 : 0); } return true; }, nullptr ); apiRegister(F(MQTT_TOPIC_RELAY "/+"), [](ApiRequest& request) { return _relayApiTryHandle(request, [&](unsigned char id) { request.send(String(_relays[id].target_status ? 1 : 0)); return true; }); }, [](ApiRequest& request) { return _relayApiTryHandle(request, [&](unsigned char id) { return _relayHandlePayload(id, request.param(F("value"))); }); } ); apiRegister(F(MQTT_TOPIC_PULSE "/+"), [](ApiRequest& request) { return _relayApiTryHandle(request, [&](unsigned char id) { request.send(String(static_cast(_relays[id].pulse_ms) / 1000)); return true; }); }, [](ApiRequest& request) { return _relayApiTryHandle(request, [&](unsigned char id) { return _relayHandlePulsePayload(id, request.param(F("value"))); }); } ); } #endif // API_SUPPORT //------------------------------------------------------------------------------ // MQTT //------------------------------------------------------------------------------ #if MQTT_SUPPORT || API_SUPPORT const String& relayPayloadOn() { return _relay_rpc_payload_on; } const String& relayPayloadOff() { return _relay_rpc_payload_off; } const String& relayPayloadToggle() { return _relay_rpc_payload_toggle; } const char* relayPayload(PayloadStatus status) { switch (status) { case PayloadStatus::Off: return _relay_rpc_payload_off.c_str(); case PayloadStatus::On: return _relay_rpc_payload_on.c_str(); case PayloadStatus::Toggle: return _relay_rpc_payload_toggle.c_str(); case PayloadStatus::Unknown: default: return ""; } } #endif // MQTT_SUPPORT || API_SUPPORT #if MQTT_SUPPORT namespace { // TODO: it *will* handle the duplicates, but we waste memory storing them // TODO: mqttSubscribe(...) also happens multiple times // // this is not really an intended use-case though, but it is techically possible... struct RelayCustomTopicBase { RelayCustomTopicBase() = delete; RelayCustomTopicBase(const RelayCustomTopicBase&) = delete; RelayCustomTopicBase(RelayCustomTopicBase&& other) noexcept : _value(std::move(other._value)), _mode(other._mode) {} template RelayCustomTopicBase(T&& value, RelayMqttTopicMode mode) : _value(std::forward(value)), _mode(mode) {} RelayCustomTopicBase& operator=(const char* const value) { _value = value; return *this; } RelayCustomTopicBase& operator=(const String& value) { _value = value; return *this; } RelayCustomTopicBase& operator=(String&& value) noexcept { _value = std::move(value); return *this; } RelayCustomTopicBase& operator=(RelayMqttTopicMode mode) noexcept { _mode = mode; return *this; } String&& get() && { return std::move(_value); } const String& value() const { return _value; } RelayMqttTopicMode mode() const { return _mode; } private: String _value; RelayMqttTopicMode _mode; }; struct RelayCustomTopic { RelayCustomTopic() = delete; RelayCustomTopic(const RelayCustomTopic&) = delete; RelayCustomTopic(RelayCustomTopic&&) = delete; RelayCustomTopic(size_t id, RelayCustomTopicBase&& base) : _id(id), _topic(std::move(base).get()), _parts(_topic), _mode(base.mode()) {} unsigned char id() const { return _id; } const char* const c_str() const { return _topic.c_str(); } const String& topic() const { return _topic; } const PathParts& parts() const { return _parts; } const RelayMqttTopicMode mode() const { return _mode; } bool match(const String& other) const { PathParts parts(other); return _parts.match(parts); } bool match(const PathParts& parts) const { return _parts.match(parts); } private: unsigned char _id; String _topic; PathParts _parts; RelayMqttTopicMode _mode; }; std::forward_list _relay_custom_topics; void _relayMqttSubscribeCustomTopics() { const size_t relays { relayCount() }; if (!relays) { return; } static std::vector topics; for (size_t id = 0; id < relays; ++id) { topics.emplace_back(_relayMqttTopicSub(id), _relayMqttTopicMode(id)); } settings::kv_store.foreach([&](settings::kvs_type::KeyValueResult&& kv) { const char* const SubPrefix = "relayTopicSub"; const char* const ModePrefix = "relayTopicMode"; if ((kv.key.length <= strlen(SubPrefix)) && (kv.key.length <= strlen(ModePrefix))) { return; } if (!kv.value.length) { return; } const auto key = kv.key.read(); unsigned char id; if (key.startsWith(SubPrefix)) { if (_relayTryParseId(key.c_str() + strlen(SubPrefix), id)) { topics[id] = std::move(kv.value.read()); } } else if (key.startsWith(ModePrefix)) { using namespace settings::internal; if (_relayTryParseId(key.c_str() + strlen(ModePrefix), id)) { topics[id] = convert(kv.value.read()); } } }); _relay_custom_topics.clear(); for (unsigned char id = 0; id < relays; ++id) { RelayCustomTopicBase& topic = topics[id]; auto& value = topic.value(); if (!value.length()) { continue; } mqttSubscribeRaw(value.c_str()); _relay_custom_topics.emplace_front(id, std::move(topic)); } topics.clear(); } void _relayMqttPublishCustomTopic(unsigned char id) { const String topic = getSetting({"relayTopicPub", id}, _relayMqttTopicPub(id)); if (!topic.length()) { return; } auto status = _relayPayloadStatus(id); auto mode = getSetting({"relayTopicMode", id}, _relayMqttTopicMode(id)); if (mode == RelayMqttTopicMode::Inverse) { status = _relayInvertStatus(status); } mqttSendRaw(topic.c_str(), relayPayload(status)); } } // namespace void _relayMqttReport(unsigned char id) { if (id < _relays.size()) { if (_relays[id].report) { _relays[id].report = false; mqttSend(MQTT_TOPIC_RELAY, id, relayPayload(_relayPayloadStatus(id))); } if (_relays[id].group_report) { _relays[id].group_report = false; _relayMqttPublishCustomTopic(id); } } } void _relayMqttReportAll() { for (unsigned int id=0; id < _relays.size(); id++) { mqttSend(MQTT_TOPIC_RELAY, id, relayPayload(_relayPayloadStatus(id))); } } void relayStatusWrap(unsigned char id, PayloadStatus value, bool is_group_topic) { #if MQTT_SUPPORT const auto forward = mqttForward(); #else const auto forward = false; #endif switch (value) { case PayloadStatus::Off: relayStatus(id, false, forward, !is_group_topic); break; case PayloadStatus::On: relayStatus(id, true, forward, !is_group_topic); break; case PayloadStatus::Toggle: relayToggle(id, true, true); break; case PayloadStatus::Unknown: default: _relays[id].report = true; _relayMqttReport(id); break; } } bool _relayMqttHeartbeat(heartbeat::Mask mask) { if (mask & heartbeat::Report::Relay) _relayMqttReportAll(); return mqttConnected(); } void _relayMqttHandleCustomTopic(const String& topic, const char* payload) { PathParts received(topic); for (auto& topic : _relay_custom_topics) { if (topic.match(received)) { auto status = relayParsePayload(payload); if (topic.mode() == RelayMqttTopicMode::Inverse) { status = _relayInvertStatus(status); } const auto id = topic.id(); _relayHandleStatus(id, status); _relays[id].group_report = false; } } } void _relayMqttHandleDisconnect() { settings::kv_store.foreach([](settings::kvs_type::KeyValueResult&& kv) { const char* const prefix = "relayMqttDisc"; if (kv.key.length <= strlen(prefix)) { return; } const auto key = kv.key.read(); if (key.startsWith(prefix)) { unsigned char id; if (_relayTryParseId(key.c_str() + strlen(prefix), id)) { const auto value = kv.value.read(); _relayHandleStatus(id, relayParsePayload(value.c_str())); } } }); } void relayMQTTCallback(unsigned int type, const char * topic, const char * payload) { static bool connected { false }; if (!relayCount()) { return; } if (type == MQTT_CONNECT_EVENT) { // Subscribe to own /set topic char relay_topic[strlen(MQTT_TOPIC_RELAY) + 3]; snprintf_P(relay_topic, sizeof(relay_topic), PSTR("%s/+"), MQTT_TOPIC_RELAY); mqttSubscribe(relay_topic); // Subscribe to pulse topic char pulse_topic[strlen(MQTT_TOPIC_PULSE) + 3]; snprintf_P(pulse_topic, sizeof(pulse_topic), PSTR("%s/+"), MQTT_TOPIC_PULSE); mqttSubscribe(pulse_topic); _relayMqttSubscribeCustomTopics(); connected = true; return; } if (type == MQTT_MESSAGE_EVENT) { String t = mqttMagnitude((char *) topic); auto is_relay = t.startsWith(MQTT_TOPIC_RELAY); auto is_pulse = t.startsWith(MQTT_TOPIC_PULSE); if (is_relay || is_pulse) { unsigned char id; if (!_relayTryParseIdFromPath(t.c_str(), id)) { return; } if (is_relay) { _relayHandlePayload(id, payload); _relays[id].report = mqttForward(); return; } if (is_pulse) { _relayHandlePulsePayload(id, payload); _relays[id].report = mqttForward(); return; } } _relayMqttHandleCustomTopic(topic, payload); return; } if (type == MQTT_DISCONNECT_EVENT) { if (connected) { connected = false; _relayMqttHandleDisconnect(); } return; } } void relaySetupMQTT() { mqttHeartbeat(_relayMqttHeartbeat); mqttRegister(relayMQTTCallback); } #endif //------------------------------------------------------------------------------ // Settings //------------------------------------------------------------------------------ #if TERMINAL_SUPPORT void _relayInitCommands() { terminalRegisterCommand(F("RELAY"), [](const terminal::CommandContext& ctx) { auto showRelays = [&](unsigned char start, unsigned char stop, bool full = true) { for (unsigned char index = start; index < stop; ++index) { auto& relay = _relays[index]; char pulse_info[64] = ""; if ((relay.pulse != RelayPulse::None) && (relay.pulse_ms)) { snprintf_P(pulse_info, sizeof(pulse_info), PSTR(" Pulse=%s Time=%u"), _relayPulseToPayload(relay.pulse), relay.pulse_ms); } char extended_info[64] = ""; if (full) { int index = 0; if (index >= 0 && relay.delay_on) { index += snprintf_P(extended_info + index, sizeof(extended_info), PSTR(" DelayOn=%u"), relay.delay_on); } if (index >= 0 && relay.delay_off) { index += snprintf_P(extended_info + index, sizeof(extended_info), PSTR(" DelayOff=%u"), relay.delay_off); } if (index >= 0 && relay.lock != RelayLock::None) { index += snprintf_P(extended_info + index, sizeof(extended_info), PSTR(" Lock=%s"), _relayLockToPayload(relay.lock)); } } ctx.output.printf_P(PSTR("relay%u {Prov=%s Current=%s Target=%s%s%s}\n"), index, relay.provider->id(), relay.current_status ? "ON" : "OFF", relay.target_status ? "ON" : "OFF", pulse_info, extended_info ); } }; if (ctx.argc == 1) { showRelays(0, _relays.size()); terminalOK(ctx); return; } unsigned char id; if (!_relayTryParseId(ctx.argv[1].c_str(), id)) { terminalError(ctx, F("Invalid relayID")); return; } if (ctx.argc > 2) { auto status = relayParsePayload(ctx.argv[2].c_str()); if (PayloadStatus::Unknown == status) { terminalError(ctx, F("Invalid status")); return; } _relayHandleStatus(id, status); } showRelays(id, id + 1, false); terminalOK(ctx); }); } #endif // TERMINAL_SUPPORT //------------------------------------------------------------------------------ void _relayReport(unsigned char id [[gnu::unused]], bool status [[gnu::unused]]) { #if BROKER_SUPPORT StatusBroker::Publish(MQTT_TOPIC_RELAY, id, status); #endif #if MQTT_SUPPORT _relayMqttReport(id); #endif #if WEB_SUPPORT _relayWsReport(); #endif } /** * Walks the relay vector processing only those relays * that have to change to the requested mode * @bool mode Requested mode */ void _relayProcess(bool mode) { bool changed = false; for (unsigned char id = 0; id < _relays.size(); id++) { bool target = _relays[id].target_status; // Only process the relays we have to change if (target == _relays[id].current_status) continue; // Only process the relays we have to change to the requested mode if (target != mode) continue; // Only process if the change delay has expired if (_relays[id].change_delay && (millis() - _relays[id].change_start < _relays[id].change_delay)) continue; // Purge existing delay in case of cancelation _relays[id].change_delay = 0; changed = true; DEBUG_MSG_P(PSTR("[RELAY] #%d set to %s\n"), id, target ? "ON" : "OFF"); // Call the provider to perform the action _relays[id].current_status = target; _relays[id].provider->change(target); if (_relay_status_change) { _relay_status_change(id, target); } _relayReport(id, target); if (!_relayRecursive) { relayPulse(id); // We will trigger a eeprom save only if // we care about current relay status on boot const auto boot_mode = getSetting({"relayBoot", id}, _relayBootMode(id)); const bool save_eeprom = ((RELAY_BOOT_SAME == boot_mode) || (RELAY_BOOT_TOGGLE == boot_mode)); _relay_save_timer.once_ms(RELAY_SAVE_DELAY, relaySave, save_eeprom); } _relays[id].report = false; _relays[id].group_report = false; } // Whenever we are using sync modes and any relay had changed the state, check if we can unlock const bool needs_unlock = ((_relay_sync_mode == RELAY_SYNC_NONE_OR_ONE) || (_relay_sync_mode == RELAY_SYNC_ONE)); if (_relay_sync_locked && needs_unlock && changed) { _relaySyncUnlock(); } } //------------------------------------------------------------------------------ // Setup //------------------------------------------------------------------------------ void _relayLoop() { _relayProcess(false); _relayProcess(true); #if WEB_SUPPORT if (_relay_report_ws) { wsPost(_relayWebSocketUpdate); _relay_report_ws = false; } #endif } // Dummy relays for virtual light switches (hardware-less), Sonoff Dual, Sonoff RF Bridge and Tuya void relaySetupDummy(size_t size, bool reconfigure) { if (size == _relayDummy) return; const size_t new_size = ((_relays.size() - _relayDummy) + size); if (new_size > RelaysMax) return; _relayDummy = size; _relays.resize(new_size); if (reconfigure) { _relayConfigure(); } #if BROKER_SUPPORT ConfigBroker::Publish("relayDummy", String(int(size))); #endif } constexpr size_t _relayAdhocPins() { return 0 #if RELAY1_PIN != GPIO_NONE + 1 #endif #if RELAY2_PIN != GPIO_NONE + 1 #endif #if RELAY3_PIN != GPIO_NONE + 1 #endif #if RELAY4_PIN != GPIO_NONE + 1 #endif #if RELAY5_PIN != GPIO_NONE + 1 #endif #if RELAY6_PIN != GPIO_NONE + 1 #endif #if RELAY7_PIN != GPIO_NONE + 1 #endif #if RELAY8_PIN != GPIO_NONE + 1 #endif ; } struct RelayGpioProviderCfg { GpioBase* base; unsigned char main; unsigned char reset; }; RelayGpioProviderCfg _relayGpioProviderCfg(unsigned char index) { return { gpioBase(getSetting({"relayGPIOType", index}, _relayPinType(index))), getSetting({"relayGPIO", index}, _relayPin(index)), getSetting({"relayResetGPIO", index}, _relayResetPin(index))}; } using GpioCheck = bool(*)(unsigned char); std::unique_ptr _relayGpioProvider(unsigned char index, RelayType type) { auto cfg = _relayGpioProviderCfg(index); if (!cfg.base) { return nullptr; } auto main = gpioRegister(*cfg.base, cfg.main); if (!main) { return nullptr; } auto reset = gpioRegister(*cfg.base, cfg.reset); return std::make_unique( index, type, std::move(main), std::move(reset) ); } RelayProviderBasePtr _relaySetupProvider(unsigned char index) { auto provider = getSetting({"relayProv", index}, _relayProvider(index)); auto type = getSetting({"relayType", index}, _relayType(index)); RelayProviderBasePtr result; switch (provider) { case RelayProvider::Dummy: result = std::make_unique(); break; case RelayProvider::Gpio: result = _relayGpioProvider(index, type); break; case RelayProvider::Stm: #if RELAY_PROVIDER_STM_SUPPORT result = std::make_unique(index); #endif break; case RelayProvider::Dual: #if RELAY_PROVIDER_DUAL_SUPPORT result = std::make_unique(index); #endif break; case RelayProvider::None: break; } return result; } void _relaySetup() { auto relays = _relays.size(); _relays.reserve(relays + _relayAdhocPins()); for (unsigned char id = relays; id < RelaysMax; ++id) { auto impl = _relaySetupProvider(id); if (!impl) { break; } if (!impl->setup()) { break; } _relays.emplace_back(std::move(impl)); } relaySetupDummy(getSetting("relayDummy", DUMMY_RELAY_COUNT)); } void relaySetup() { _relaySettingsMigrate(migrateVersion()); _relaySetup(); _relayConfigure(); _relayBootAll(); _relayLoop(); #if WEB_SUPPORT relaySetupWS(); #endif #if API_SUPPORT relaySetupAPI(); #endif #if MQTT_SUPPORT relaySetupMQTT(); #endif #if TERMINAL_SUPPORT _relayInitCommands(); #endif // Main callbacks espurnaRegisterLoop(_relayLoop); espurnaRegisterReload(_relayConfigure); } bool relayAdd(RelayProviderBasePtr&& provider) { if (provider && provider->setup()) { static bool scheduled { false }; _relays.emplace_back(std::move(provider)); if (!scheduled) { schedule_function([]() { _relayConfigure(); _relayBootAll(); scheduled = false; }); } return true; } return false; } #endif // RELAY_SUPPORT == 1