upd

carrierPauseIfIdle/carrierResume
no grammar fix
2026-03-14 05:14:45 +00:00 · 2026-03-11 16:57:55 +03:00 · 2026-02-06 16:06:23 +03:00 · 2025-10-17 17:28:01 +03:00 · 2025-10-17 17:25:09 +03:00 · 2025-09-05 18:24:19 +03:00
8 changed files with 568 additions and 86 deletions
--- a/.vscode/arduino.json
+++ b/.vscode/arduino.json
@ -1,7 +1,5 @@
 {
    "board": "STMicroelectronics:stm32:GenF4",
    "port": "COM17",
-    "prebuild": "if exist bin rd /s /q bin",
+    "prebuild": "if exist bin rd /s /q bin"
    "configuration": "clock=25MHz,pnum=MAKET_F401RETX,upload_method=swdMethod,xserial=generic,usb=CDCgen,xusb=FS,opt=osstd,dbg=none,rtlib=nano",
    "sketch": "IR-protocol.ino"
 }
--- a/IR_Decoder.cpp
+++ b/IR_Decoder.cpp
@ -61,6 +61,7 @@ void IR_Decoder::tick()
 void IR_Decoder::_tick()
 {
    IR_DecoderRaw::tick();
    if (availableRaw())
    {
 #ifdef IRDEBUG_INFO
@ -97,9 +98,13 @@ void IR_Decoder::_tick()
        }
        gotRaw.set(&packInfo, id);
    }
-    if (isWaitingAcceptSend && millis() - acceptSendTimer > 75)
+    if (isWaitingAcceptSend && millis() - acceptSendTimer > acceptDelay)
    {
        encoder->sendAccept(addrAcceptSendTo, acceptCustomByte);
        isWaitingAcceptSend = false;
    }
 }
 bool IR_Decoder::isReceive(uint8_t type) {
    return (msgTypeReceive & 0b11111000) && ((msgTypeReceive & IR_MASK_MSG_TYPE) == type);
 } 
--- a/IR_Decoder.h
+++ b/IR_Decoder.h
@ -14,7 +14,7 @@ private:
    bool isWaitingAcceptSend;
    uint16_t addrAcceptSendTo;
-    uint16_t acceptDelay = 75;
+    uint16_t acceptDelay = IR_ResponseDelay;
    uint8_t acceptCustomByte;
 public:
@ -32,6 +32,8 @@ public:
    void enable();
    void disable();
    bool isReceive(uint8_t type);
    ~IR_Decoder();
    static void tick();
--- a/IR_DecoderRaw.cpp
+++ b/IR_DecoderRaw.cpp
@ -112,16 +112,37 @@ void IR_DecoderRaw::firstRX()
 void IR_DecoderRaw::listenStart()
 {
-    if (isRecive && ((micros() - prevRise) > IR_timeout * 2))
+    if (isReciveRaw && ((micros() - prevRise) > IR_timeout * 2))
    {
        // Serial.print("\nlis>");
-        isRecive = false;
+        isReciveRaw = false;
        firstRX();
    }
 }
 // ---- быстрая проверка конца пакета ---------------------------------
 inline void IR_DecoderRaw::checkTimeout()
 {
    if (!isRecive) return;     // уже не принимаем – нечего проверять
    if (micros() - lastEdgeTime > IR_timeout * 2U)
    {
        isRecive = false;      // приём завершён
        msgTypeReceive = 0;
        // firstRX();             // подготовка к новому пакету
        lastEdgeTime = micros(); // защита от повторного срабатывания
    }
 }
 // ====================================================================
 void IR_DecoderRaw::tick()
 {
    // FrontStorage *currentFrontPtr;
    // noInterrupts();
    // currentFrontPtr = subBuffer.pop();
    // interrupts();
    FrontStorage currentFront;
    noInterrupts();
    listenStart();
@ -130,12 +151,24 @@ void IR_DecoderRaw::tick()
    if (currentFrontPtr == nullptr)
    {
        isSubBufferOverflow = false;
        checkTimeout();          // <--- новое место проверки
        interrupts();
        return;
    } // Если данных нет - ничего не делаем
    currentFront = *currentFrontPtr;
    interrupts();
    // ---------- буфер пуст: фронтов нет, проверяем тайм-аут ----------
    // if (currentFrontPtr == nullptr)
    // {
    //     isSubBufferOverflow = false;
    //     return;
    // }
    // // ---------- есть фронт: продолжаем обработку ----------
    // FrontStorage currentFront = *currentFrontPtr;
    lastEdgeTime = currentFront.time;     // запоминаем любой фронт
    ////////////////////////////////////////////////////////////////////////////////////////////////////////////
    if (currentFront.dir)
@ -197,7 +230,7 @@ void IR_DecoderRaw::tick()
    digitalWrite(errOut, currentFront.dir);
 #endif
-    if (currentFront.time > prevRise && currentFront.time - prevRise > IR_timeout * 2 && !isRecive)
+    if (currentFront.time > prevRise && currentFront.time - prevRise > IR_timeout * 2 && !isReciveRaw)
    { // первый
 #ifdef IRDEBUG
        errPulse(up, 50);
@ -209,6 +242,7 @@ void IR_DecoderRaw::tick()
        isPreamb = true;
        isRecive = true;
        isReciveRaw = true;
        isWrongPack = false;
    }
@ -441,6 +475,8 @@ void IR_DecoderRaw::writeToBuffer(bool bit)
    if (isBufferOverflow || isPreamb || isWrongPack)
    {
        isRecive = false;
        isReciveRaw = false;
        msgTypeReceive = 0;
        return;
    }
@ -564,6 +600,8 @@ void IR_DecoderRaw::writeToBuffer(bool bit)
            packInfo.rTime = riseSyncTime;
            isRecive = false;
            isReciveRaw = false;
            msgTypeReceive = 0;
            isAvailable = crcCheck(packSize - crcBytes, crcValue);
 #ifdef BRUTEFORCE_CHECK
@ -594,6 +632,12 @@ void IR_DecoderRaw::writeToBuffer(bool bit)
        OUT_BRUTEFORCE:;
 #endif
        }
        if (packSize && (i_dataBuffer == 8)) {
            msgTypeReceive = (dataBuffer[0]>>5) | 0b11111000;
            // SerialUSB.println(msgTypeReceive & IR_MASK_MSG_TYPE);
        }
    }
    //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
--- a/IR_DecoderRaw.h
+++ b/IR_DecoderRaw.h
@ -23,6 +23,7 @@
 #define riseTimeMin (riseTime - riseTolerance)
 #define aroundRise(t) (riseTimeMin < t && t < riseTimeMax)
 #define IR_timeout (riseTimeMax * (8 + syncBits + 1)) // us // таймаут в 8 data + 3 sync + 1
 constexpr uint16_t IR_ResponseDelay = ((uint16_t)(((bitTime+riseTolerance) * (8 + syncBits + 1))*2.7735))/1000;
 class IR_Encoder;
 class IR_DecoderRaw : virtual public IR_FOX
@ -31,6 +32,7 @@ class IR_DecoderRaw : virtual public IR_FOX
 protected:
 PackInfo packInfo;
 uint8_t msgTypeReceive = 0;
 IR_Encoder *encoder; // Указатель на парный передатчик
 bool availableRaw();
@ -47,7 +49,7 @@ public:
    inline bool isOverflow() { return isBufferOverflow; }; // Буффер переполнился
    bool isSubOverflow();
-    inline bool isReciving() { return isBufferOverflow; }; // Возвращает true, если происходит приём пакета
+    volatile inline bool isReciving() { return isRecive; }; // Возвращает true, если происходит приём пакета
    //////////////////////////////////////////////////////////////////////////
 private:
@ -64,6 +66,8 @@ private:
    uint16_t riseSyncTime = bitTime; // Подстраиваемое время бита в мкс
    volatile uint32_t lastEdgeTime = 0;   // время последнего фронта
    ////////////////////////////////////////////////////////////////////////
    volatile uint32_t currentSubBufferIndex; // Счетчик текущей позиции во вспомогательном буфере фронтов/спадов
@ -99,7 +103,9 @@ private:
    int16_t bufBitPos = 0;         // Позиция для записи бита в буффер
 private:
-    void listenStart(); // @brief Слушатель для работы isReciving()
+bool isReciveRaw;
    void listenStart();
    void checkTimeout();                  // 
    /// @brief Проверка CRC. Проверяет len байт со значением crc, пришедшим в пакете
    /// @param len Длина в байтах проверяемых данных
--- a/IR_Encoder.cpp
+++ b/IR_Encoder.cpp
@ -1,15 +1,14 @@
 #include "IR_Encoder.h"
 #include "IR_DecoderRaw.h"
 #include <string.h>
 #define LoopOut 12
 #define ISR_Out 10
 #define TestOut 13
-std::list<IR_Encoder *> &IR_Encoder::get_enc_list() // определение функции
+IR_Encoder *IR_Encoder::head = nullptr;
-{
+IR_Encoder *IR_Encoder::last = nullptr;
-    static std::list<IR_Encoder *> dec_list; // статическая локальная переменная
+volatile bool IR_Encoder::carrierStopPending = false;
    return dec_list;                         // возвращается ссылка на переменную
 }
 IR_Encoder::IR_Encoder(uint8_t pin, uint16_t addr, IR_DecoderRaw *decPair, bool autoHandle)
 {
@ -32,45 +31,272 @@ IR_Encoder::IR_Encoder(uint8_t pin, uint16_t addr, IR_DecoderRaw *decPair, bool
    if (autoHandle)
    {
-        get_enc_list().push_back(this);
+        if (IR_Encoder::head == nullptr)
        {
        IR_Encoder::head = this;
        }
        if (last != nullptr)
        {
        last->next = this;
        }
        last = this;
        pinMode(pin, OUTPUT);
    }
 };
-HardwareTimer IR_Encoder::IR_Timer;
+HardwareTimer* IR_Encoder::IR_Timer = nullptr;
 IR_Encoder::ExternalTxStartFn IR_Encoder::externalTxStartFn = nullptr;
 IR_Encoder::ExternalTxBusyFn IR_Encoder::externalTxBusyFn = nullptr;
 void *IR_Encoder::externalTxCtx = nullptr;
-inline HardwareTimer* IR_Encoder::get_IR_Timer(){return &IR_Encoder::IR_Timer;}
+inline HardwareTimer* IR_Encoder::get_IR_Timer(){return IR_Encoder::IR_Timer;}
-// void Encoder_ISR(){
+
-//     IR_Encoder::isr();
+void IR_Encoder::carrierResume() {
-// }
+    if (IR_Timer != nullptr)
-void IR_Encoder::begin(HardwareTimer timer, uint8_t channel, IRQn_Type IRQn){
+        IR_Timer->resume();
-    //TODO: check std::bind isr func
+}
-    // IR_Timer = timer;
+
-    // IR_Timer.setOverflow(carrierFrec * 2, HERTZ_FORMAT);
+void IR_Encoder::carrierPauseIfIdle() {
-    // IR_Timer.attachInterrupt(channel, Encoder_ISR);
+    for (IR_Encoder *p = head; p != nullptr; p = p->next)
-    // NVIC_SetPriority(IRQn, 0);
+        if (p->isSending)
-    // IR_Timer.resume();
+            return;
    if (IR_Timer != nullptr)
        IR_Timer->pause();
 }
 void IR_Encoder::tick() {
    if (!carrierStopPending)
        return;
    carrierStopPending = false;
    carrierPauseIfIdle();
 }
 void IR_Encoder::begin(HardwareTimer* timer, uint8_t channel, IRQn_Type IRQn, uint8_t priority, void(*isrCallback)()){
    IR_Timer = timer;
    if(IR_Timer == nullptr) return;
    IR_Timer->pause();
    IR_Timer->setOverflow(carrierFrec * 2, HERTZ_FORMAT);
    IR_Timer->attachInterrupt(channel, (isrCallback == nullptr ? IR_Encoder::isr : isrCallback));
    NVIC_SetPriority(IRQn, priority);
    IR_Timer->pause();
 }
 void IR_Encoder::beginClockOnly(HardwareTimer *timer)
 {
    IR_Timer = timer;
    if (IR_Timer == nullptr)
        return;
    IR_Timer->pause();
    IR_Timer->setOverflow(carrierFrec * 2, HERTZ_FORMAT);
    IR_Timer->pause();
 }
 void IR_Encoder::setExternalTxBackend(ExternalTxStartFn startFn, ExternalTxBusyFn busyFn, void *ctx)
 {
    externalTxStartFn = startFn;
    externalTxBusyFn = busyFn;
    externalTxCtx = ctx;
 }
 void IR_Encoder::externalFinishSend()
 {
    if (!isSending)
        return;
    // Force output low.
    if (port != nullptr) {
        port->BSRR = ((uint32_t)mask) << 16;
    }
    isSending = false;
    setDecoder_isSending();
 }
 size_t IR_Encoder::buildGateRuns(const uint8_t *packet, uint8_t len, IR_TxGateRun *outRuns, size_t maxRuns)
 {
    if (packet == nullptr || outRuns == nullptr || maxRuns == 0)
    {
        return 0;
    }
    if (len == 0 || len > dataByteSizeMax)
    {
        return 0;
    }
    // Copy into fixed-size buffer to match original encoder behavior (safe reads past sendLen).
    uint8_t sendBufferLocal[dataByteSizeMax] = {0};
    memcpy(sendBufferLocal, packet, len);
    uint8_t sendLenLocal = len;
    uint8_t toggleCounterLocal = preambToggle;
    uint8_t dataBitCounterLocal = bitPerByte - 1;
    uint8_t dataByteCounterLocal = 0;
    uint8_t preambFrontCounterLocal = preambPulse * 2 - 1;
    uint8_t dataSequenceCounterLocal = bitPerByte * 2;
    uint8_t syncSequenceCounterLocal = syncBits * 2;
    bool syncLastBitLocal = false;
    SignalPart signalLocal = preamb;
    bool stateLocal = HIGH;
    uint8_t *currentBitSequenceLocal = bitHigh;
    size_t runCount = 0;
    while (true)
    {
        const bool gate = stateLocal;
        const uint16_t runLenTicks = (uint16_t)toggleCounterLocal + 1U;
        if (runCount > 0 && outRuns[runCount - 1].gate == gate)
        {
            outRuns[runCount - 1].lenTicks = (uint16_t)(outRuns[runCount - 1].lenTicks + runLenTicks);
        }
        else
        {
            if (runCount >= maxRuns)
            {
                return 0;
            }
            outRuns[runCount].gate = gate;
            outRuns[runCount].lenTicks = runLenTicks;
            runCount++;
        }
        // Advance state to the next run boundary (equivalent to ISR iteration when toggleCounter == 0).
        while (true)
        {
            switch (signalLocal)
            {
            case noSignal:
                return runCount;
            case preamb:
                if (preambFrontCounterLocal)
                {
                    preambFrontCounterLocal--;
                    toggleCounterLocal = preambToggle;
                    break;
                }
                // End of preamble.
                signalLocal = data;
                stateLocal = !LOW;
                continue;
            case data:
                if (dataSequenceCounterLocal)
                {
                    if (!(dataSequenceCounterLocal & 1U))
                    {
                        currentBitSequenceLocal = ((sendBufferLocal[dataByteCounterLocal] >> dataBitCounterLocal) & 1U) ? bitHigh : bitLow;
                        dataBitCounterLocal--;
                    }
                    toggleCounterLocal = currentBitSequenceLocal[!stateLocal];
                    dataSequenceCounterLocal--;
                    break;
                }
                // End of data byte.
                syncLastBitLocal = ((sendBufferLocal[dataByteCounterLocal]) & 1U);
                dataByteCounterLocal++;
                dataBitCounterLocal = bitPerByte - 1;
                dataSequenceCounterLocal = bitPerByte * 2;
                signalLocal = sync;
                continue;
            case sync:
                if (syncSequenceCounterLocal)
                {
                    if (!(syncSequenceCounterLocal & 1U))
                    {
                        if (syncSequenceCounterLocal == 2)
                        {
                            currentBitSequenceLocal = ((sendBufferLocal[dataByteCounterLocal]) & 0b10000000) ? bitLow : bitHigh;
                        }
                        else
                        {
                            currentBitSequenceLocal = syncLastBitLocal ? bitLow : bitHigh;
                            syncLastBitLocal = !syncLastBitLocal;
                        }
                    }
                    toggleCounterLocal = currentBitSequenceLocal[!stateLocal];
                    syncSequenceCounterLocal--;
                    break;
                }
                // End of sync.
                signalLocal = data;
                syncSequenceCounterLocal = syncBits * 2;
                if (dataByteCounterLocal >= sendLenLocal)
                {
                    signalLocal = noSignal;
                }
                continue;
            default:
                return 0;
            }
            stateLocal = !stateLocal;
            break;
        }
    }
 }
 void IR_Encoder::enable()
 {
-    auto &enc_list = get_enc_list();
+    bool exist = false;
-    if (std::find(enc_list.begin(), enc_list.end(), this) == enc_list.end())
+    IR_Encoder *current = IR_Encoder::head;
    while (current != nullptr)
    {
-        enc_list.push_back(this);
+        exist = (current == this);
        if (exist) break;
        current = current->next;
    }
    if (!exist)
    {
        if (IR_Encoder::head == nullptr)
        {
            IR_Encoder::head = this;
            last = this;
        }
        else
        {
            last->next = this;
            last = this;
        }
        this->next = nullptr; // Указываем, что следующий за этим элементом — nullptr
    }
    pinMode(pin, OUTPUT);
 }
 void IR_Encoder::disable()
 {
-    auto &enc_list = get_enc_list();
+    IR_Encoder *current = IR_Encoder::head;
-    auto it = std::find(enc_list.begin(), enc_list.end(), this);
+    IR_Encoder *prev = nullptr;
-    if (it != enc_list.end())
+
    while (current != nullptr)
    {
-        enc_list.erase(it);
+        if (current == this) break;
        prev = current;
        current = current->next;
    }
    if (current != nullptr) // Элемент найден в списке
    {
        if (prev != nullptr)
        {
            prev->next = current->next; // Убираем текущий элемент из списка
        }
        else
        {
            IR_Encoder::head = current->next; // Удаляемый элемент был первым
        }
        if (current == last)
        {
            last = prev; // Если удаляется последний элемент, обновляем last
        }
    }
    pinMode(pin, INPUT);
 }
@ -84,25 +310,23 @@ void IR_Encoder::setBlindDecoders(IR_DecoderRaw *decoders[], uint8_t count)
    blindDecoders = decoders;
 }
-IR_Encoder::~IR_Encoder()
+IR_Encoder::~IR_Encoder(){};
 {
    get_enc_list().remove(this);
 };
-void IR_Encoder::sendData(uint16_t addrTo, uint8_t dataByte, bool needAccept)
+IR_SendResult IR_Encoder::sendData(uint16_t addrTo, uint8_t dataByte, bool needAccept)
 {
-    sendData(addrTo, &dataByte, 1, needAccept);
+    return sendData(addrTo, &dataByte, 1, needAccept);
 }
-void IR_Encoder::sendData(uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept){
+IR_SendResult IR_Encoder::sendData(uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept){
-    sendDataFULL(id, addrTo, data, len, needAccept);
+    return sendDataFULL(id, addrTo, data, len, needAccept);
 }
-void IR_Encoder::sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept)
+IR_SendResult IR_Encoder::sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept)
 {
    if (len > bytePerPack)
    {
-        return;
+        Serial.println("IR Pack to big");
        return IR_SendResult(false, 0);
    }
    constexpr uint8_t dataStart = msgBytes + addrBytes + addrBytes;
    memset(sendBuffer, 0x00, dataByteSizeMax);
@ -131,6 +355,19 @@ void IR_Encoder::sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data,
    sendBuffer[packSize - crcBytes] = crc8(sendBuffer, 0, packSize - crcBytes, poly1) & 0xFF;
    sendBuffer[packSize - crcBytes + 1] = crc8(sendBuffer, 0, packSize - crcBytes + 1, poly2) & 0xFF;
    //* вывод итогового буфера
    // Serial.print("IR SEND [len=");
    // Serial.print(packSize);
    // Serial.print("] : ");
    // for (uint8_t i = 0; i < packSize; i++)
    // {
    //     if (sendBuffer[i] < 0x10)
    //         Serial.print('0');
    //     Serial.print(sendBuffer[i], HEX);
    //     Serial.print(' ');
    // }
    // Serial.println();
    // if (decPair != nullptr) {
    //     decPair->isWaitingAccept = ((msgType >> 5) & IR_MASK_MSG_TYPE == IR_MSG_DATA_ACCEPT);
    //     if (decPair->isWaitingAccept) {
@ -140,9 +377,14 @@ void IR_Encoder::sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data,
    // отправка
    rawSend(sendBuffer, packSize);
    // Возвращаем результат отправки
    uint32_t sendTime = calculateSendTime(packSize);
    return IR_SendResult(true, sendTime);
 }
-void IR_Encoder::sendAccept(uint16_t addrTo, uint8_t customByte)
+
 IR_SendResult IR_Encoder::sendAccept(uint16_t addrTo, uint8_t customByte)
 {
    constexpr uint8_t packsize = msgBytes + addrBytes + 1U + crcBytes;
    memset(sendBuffer, 0x00, dataByteSizeMax);
@ -163,9 +405,13 @@ void IR_Encoder::sendAccept(uint16_t addrTo, uint8_t customByte)
    sendBuffer[5] = crc8(sendBuffer, 0, 5, poly2) & 0xFF;
    rawSend(sendBuffer, packsize);
    // Возвращаем результат отправки
    uint32_t sendTime = calculateSendTime(packsize);
    return IR_SendResult(true, sendTime);
 }
-void IR_Encoder::sendRequest(uint16_t addrTo)
+IR_SendResult IR_Encoder::sendRequest(uint16_t addrTo)
 {
    constexpr uint8_t packsize = msgBytes + addrBytes + addrBytes + crcBytes;
    memset(sendBuffer, 0x00, dataByteSizeMax);
@ -185,28 +431,32 @@ void IR_Encoder::sendRequest(uint16_t addrTo)
    sendBuffer[6] = crc8(sendBuffer, 0, 6, poly2) & 0xFF;
    rawSend(sendBuffer, packsize);
    // Возвращаем результат отправки
    uint32_t sendTime = calculateSendTime(packsize);
    return IR_SendResult(true, sendTime);
 }
-void IR_Encoder::sendBack(uint8_t data)
+IR_SendResult IR_Encoder::sendBack(uint8_t data)
 {
-    _sendBack(false, 0, &data, 1);
+    return _sendBack(false, 0, &data, 1);
 }
-void IR_Encoder::sendBack(uint8_t *data, uint8_t len)
+IR_SendResult IR_Encoder::sendBack(uint8_t *data, uint8_t len)
 {
-    _sendBack(false, 0, data, len);
+    return _sendBack(false, 0, data, len);
 }
-void IR_Encoder::sendBackTo(uint16_t addrTo, uint8_t *data, uint8_t len)
+IR_SendResult IR_Encoder::sendBackTo(uint16_t addrTo, uint8_t *data, uint8_t len)
 {
-    _sendBack(true, addrTo, data, len);
+    return _sendBack(true, addrTo, data, len);
 }
-void IR_Encoder::_sendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint8_t len)
+IR_SendResult IR_Encoder::_sendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint8_t len)
 {
    if (len > bytePerPack)
    {
-        return;
+        return IR_SendResult(false, 0);
    }
    memset(sendBuffer, 0x00, dataByteSizeMax);
    uint8_t dataStart = msgBytes + addrBytes + (isAdressed ? addrBytes : 0);
@ -238,6 +488,10 @@ void IR_Encoder::_sendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint
    // отправка
    rawSend(sendBuffer, packSize);
    // Возвращаем результат отправки
    uint32_t sendTime = calculateSendTime(packSize);
    return IR_SendResult(true, sendTime);
 }
 void IR_Encoder::setDecoder_isSending()
@ -247,6 +501,10 @@ void IR_Encoder::setDecoder_isSending()
        for (uint8_t i = 0; i < decodersCount; i++)
        {
            blindDecoders[i]->isPairSending ^= id;
            // Serial.print("setDecoder_isSending()   id = ");
            // Serial.print(id);
            // Serial.print("   isPairSending = ");
            // Serial.println(blindDecoders[i]->isPairSending);
        }
    }
 }
@ -259,6 +517,34 @@ void IR_Encoder::rawSend(uint8_t *ptr, uint8_t len)
        return;
    }
    // Проверка на переполнение буфера
    if (len > dataByteSizeMax)
    {
        return;
    }
    if (externalTxStartFn != nullptr)
    {
        if (externalTxBusyFn != nullptr && externalTxBusyFn(externalTxCtx))
        {
            return;
        }
        // Mark as sending and delegate actual signal output to external backend.
        setDecoder_isSending();
        sendLen = len;
        isSending = true;
        const bool ok = externalTxStartFn(externalTxCtx, this, ptr, len);
        if (!ok)
        {
            isSending = false;
            setDecoder_isSending();
        }
        return;
    }
    IR_Encoder::carrierResume();
    // Serial.println("START");
    setDecoder_isSending();
    // noInterrupts();
@ -277,16 +563,16 @@ void IR_Encoder::rawSend(uint8_t *ptr, uint8_t len)
    state = HIGH;
    currentBitSequence = bitHigh;
    isSending = true;
    // interrupts();
 }
 void IR_Encoder::isr()
 {
-    //  Serial.println(get_enc_list().size());
+    IR_Encoder *current = IR_Encoder::head;
-    for (const auto &element : get_enc_list())
+    while (current != nullptr)
    {
-        element->_isr();
+      current->_isr();
      current = current->next;
    }
 }
@ -314,7 +600,10 @@ void IR_Encoder::_isr()
            // сброс счетчиков
            // ...
            isSending = false;
            // Serial.println("STOP");
            setDecoder_isSending();
            carrierStopPending = true;
            // Serial.println();
            return;
            break;
@ -439,6 +728,91 @@ uint8_t IR_Encoder::bitLow[2] = {
    (bitPauseTakts / 2 + bitActiveTakts) * 2 - 1,
    (bitPauseTakts)-1};
 uint32_t IR_Encoder::calculateSendTime(uint8_t packSize) const
 {
    // Расчет времени отправки пакета в миллисекундах
    // Время преамбулы: preambPulse * 2 фронта * bitTakts тактов
    uint32_t preambTime = preambPulse * 2 * bitTakts;
    // Время данных: количество бит * bitTakts тактов
    uint32_t dataTime = packSize * 8 * bitTakts;
    // Время синхронизации: syncBits * 2 фронта * bitTakts тактов
    uint32_t syncTime = syncBits * 2 * bitTakts;
    // Общее время в тактах
    uint32_t totalTakts = preambTime + dataTime + syncTime;
    // Конвертируем в миллисекунды
    // carrierPeriod - период несущей в микросекундах
    // totalTakts * carrierPeriod / 1000 = время в миллисекундах
    uint32_t sendTimeMs = (totalTakts * carrierPeriod) / 1000;
    return sendTimeMs;
 }
 // Функции для тестирования времени отправки без фактической отправки
 uint32_t IR_Encoder::testSendTime(uint16_t addrTo, uint8_t dataByte, bool needAccept) const
 {
    return testSendTime(addrTo, &dataByte, 1, needAccept);
 }
 uint32_t IR_Encoder::testSendTime(uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept) const
 {
    return testSendTimeFULL(id, addrTo, data, len, needAccept);
 }
 uint32_t IR_Encoder::testSendTimeFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept) const
 {
    if (len > bytePerPack)
    {
        return 0; // Возвращаем 0 для недопустимого размера
    }
    uint8_t packSize = msgBytes + addrBytes + addrBytes + len + crcBytes;
    return calculateSendTime(packSize);
 }
 uint32_t IR_Encoder::testSendAccept(uint16_t addrTo, uint8_t customByte) const
 {
    constexpr uint8_t packsize = msgBytes + addrBytes + 1U + crcBytes;
    return calculateSendTime(packsize);
 }
 uint32_t IR_Encoder::testSendRequest(uint16_t addrTo) const
 {
    constexpr uint8_t packsize = msgBytes + addrBytes + addrBytes + crcBytes;
    return calculateSendTime(packsize);
 }
 uint32_t IR_Encoder::testSendBack(uint8_t data) const
 {
    return testSendBack(false, 0, &data, 1);
 }
 uint32_t IR_Encoder::testSendBack(uint8_t *data, uint8_t len) const
 {
    return testSendBack(false, 0, data, len);
 }
 uint32_t IR_Encoder::testSendBackTo(uint16_t addrTo, uint8_t *data, uint8_t len) const
 {
    return testSendBack(true, addrTo, data, len);
 }
 uint32_t IR_Encoder::testSendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint8_t len) const
 {
    if (len > bytePerPack)
    {
        return 0; // Возвращаем 0 для недопустимого размера
    }
    uint8_t packSize = msgBytes + addrBytes + (isAdressed ? addrBytes : 0) + min(uint8_t(1), len) + crcBytes;
    return calculateSendTime(packSize);
 }
 // uint8_t* IR_Encoder::bitHigh = new uint8_t[2]{
 //         (bitPauseTakts) * 2 - 0,
 //         (bitActiveTakts) * 2 - 0};
--- a/IR_Encoder.h
+++ b/IR_Encoder.h
@ -3,13 +3,32 @@
 // TODO: Отложенная передача после завершения приема
 // Структура для возврата результата отправки
 struct IR_SendResult {
    bool success;           // Флаг успешности отправки
    uint32_t sendTimeMs;    // Время отправки пакета в миллисекундах
    IR_SendResult(bool success = false, uint32_t sendTimeMs = 0) 
        : success(success), sendTimeMs(sendTimeMs) {}
 };
 class IR_DecoderRaw;
 class IR_Encoder : public IR_FOX
 {
    friend IR_DecoderRaw;
-
+    static IR_Encoder *head;
    static IR_Encoder *last;
    IR_Encoder *next;
 public:
-    static HardwareTimer IR_Timer;
+    static HardwareTimer* IR_Timer;
    struct IR_TxGateRun {
        uint16_t lenTicks; // number of timer ticks at carrierFrec*2
        bool gate;         // true: carrier enabled (output toggles), false: silent (output forced low)
    };
    using ExternalTxBusyFn = bool (*)(void *ctx);
    using ExternalTxStartFn = bool (*)(void *ctx, IR_Encoder *enc, const uint8_t *packet, uint8_t len);
 private:
    // uint16_t id; /// @brief Адрес передатчика
 public:
@ -19,8 +38,21 @@ public:
    /// @param decPair Приёмник, для которого отключается приём в момент передачи передатчиком
    IR_Encoder(uint8_t pin, uint16_t addr = 0, IR_DecoderRaw *decPair = nullptr, bool autoHandle = true);
    static void isr();
-    static void begin(HardwareTimer IR_Timer, uint8_t channel, IRQn_Type IRQn);
+    static void begin(HardwareTimer* timer, uint8_t channel, IRQn_Type IRQn, uint8_t priority, void(*isrCallback)() = nullptr);
    /** Configure timer frequency for TX clock (carrierFrec*2) without attaching ISR. */
    static void beginClockOnly(HardwareTimer *timer);
    static HardwareTimer* get_IR_Timer();
    /** Call from main loop/tick: if ISR requested carrier stop, pause timer here (not in ISR). */
    static void tick();
    /** Optional: register external TX backend (e.g. DMA driver). */
    static void setExternalTxBackend(ExternalTxStartFn startFn, ExternalTxBusyFn busyFn, void *ctx);
    /** Called by external TX backend on actual end of transmission. */
    void externalFinishSend();
    /** Build RLE runs of carrier gate for a packet (no HW access). */
    static size_t buildGateRuns(const uint8_t *packet, uint8_t len, IR_TxGateRun *outRuns, size_t maxRuns);
    void enable();
    void disable();
@ -28,30 +60,50 @@ public:
    void setBlindDecoders(IR_DecoderRaw *decoders[], uint8_t count);
    void rawSend(uint8_t *ptr, uint8_t len);
-    void sendData(uint16_t addrTo, uint8_t dataByte, bool needAccept = false);
+    IR_SendResult sendData(uint16_t addrTo, uint8_t dataByte, bool needAccept = false);
-    void sendData(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
+    IR_SendResult sendData(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
-    void sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
+    IR_SendResult sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
-    void sendAccept(uint16_t addrTo, uint8_t customByte = 0);
+    IR_SendResult sendAccept(uint16_t addrTo, uint8_t customByte = 0);
-    void sendRequest(uint16_t addrTo);
+    IR_SendResult sendRequest(uint16_t addrTo);
-    void sendBack(uint8_t data);
+    IR_SendResult sendBack(uint8_t data);
-    void sendBack(uint8_t *data = nullptr, uint8_t len = 0);
+    IR_SendResult sendBack(uint8_t *data = nullptr, uint8_t len = 0);
-    void sendBackTo(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0);
+    IR_SendResult sendBackTo(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0);
    // Функция для тестирования времени отправки без фактической отправки
    uint32_t testSendTime(uint16_t addrTo, uint8_t dataByte, bool needAccept = false) const;
    uint32_t testSendTime(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false) const;
    uint32_t testSendTimeFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false) const;
    uint32_t testSendAccept(uint16_t addrTo, uint8_t customByte = 0) const;
    uint32_t testSendRequest(uint16_t addrTo) const;
    uint32_t testSendBack(uint8_t data) const;
    uint32_t testSendBack(uint8_t *data = nullptr, uint8_t len = 0) const;
    uint32_t testSendBackTo(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0) const;
    inline bool isBusy() const { return isSending;}
    ~IR_Encoder();
    volatile bool ir_out_virtual;
 private:
    static std::list<IR_Encoder*>& get_enc_list();
    void _sendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint8_t len);
    void _isr();
 private:
    static volatile bool carrierStopPending;
    static void carrierResume();
    static void carrierPauseIfIdle();
    static ExternalTxStartFn externalTxStartFn;
    static ExternalTxBusyFn externalTxBusyFn;
    static void *externalTxCtx;
    IR_SendResult _sendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint8_t len);
    void setDecoder_isSending();
    void sendByte(uint8_t byte, bool *prev, bool LOW_FIRST);
    void addSync(bool *prev, bool *next);
    uint32_t calculateSendTime(uint8_t packSize) const;
    uint32_t testSendBack(bool isAdressed, uint16_t addrTo, uint8_t *data, uint8_t len) const;
    void send_HIGH(bool = 1);
    void send_LOW();
    void send_EMPTY(uint8_t count);
@ -94,4 +146,3 @@ private:
    uint8_t *currentBitSequence = bitLow;
    volatile SignalPart signal;
 };
--- a/IR_config.h
+++ b/IR_config.h
@ -15,7 +15,7 @@
    IR_MSG_ACCEPT с адреса 0 воспринимается всеми устройствами
 */ 
 //**** Контрольные точки ******
-#define IR_MAX_ADDR_CPU 64999
+#define IR_MAX_ADDR_CPU 63999
 #define IR_MIN_ADDR_CPU 32000
 // //***** Группы машинок ********
@ -28,11 +28,11 @@
 //********* Машинки ***********
 #define IR_MAX_CAR 31999
-#define IR_MIN_CAR 100
+#define IR_MIN_CAR 1
 //***** Пульты управления *****
-#define IR_MAX_CONTROLLER 99
+#define IR_MAX_CONTROLLER 64999
-#define IR_MIN_CONTROLLER 0
+#define IR_MIN_CONTROLLER 64000
 /*
 /```````````````````````````````````````````````` data pack `````````````````````````````````````````````\                                  
@ -52,7 +52,7 @@ msg type:
                                         //  | 01234567 |
                                         //   ----------
                                         //  | xxx..... | = тип сообщения
-                                        //  | ...xxxxx | = длина (максимум 31 бита)
+                                        //  | ...xxxxx | = длина (максимум 31 бита) - не больше 24 байт на тело пакета
                                         //   ---------- */
 #define IR_MSG_BACK 0U          //  | 000...... | = Задний сигнал машинки
 #define IR_MSG_ACCEPT 1U        //  | 001..... | = подтверждение
@ -116,13 +116,13 @@ msg type:
 typedef uint16_t crc_t;
 // #define BRUTEFORCE_CHECK                            // Перепроверяет пакет на 1 битные ошибки //TODO: зависает
-#define bytePerPack 16 // колличество байтов в пакете
+#define bytePerPack (31) // колличество байтов в пакете
 #ifndef freeFrec
 #define freeFrec false
 #endif
 #ifndef subBufferSize
-#define subBufferSize 50 // Буфер для складирования фронтов, пока их не обработают (передатчик)
+#define subBufferSize 250 // Буфер для складирования фронтов, пока их не обработают (передатчик)
 #endif
 #define preambPulse 3
@ -201,6 +201,8 @@ public:
    static void checkAddressRuleApply(uint16_t address, uint16_t id, bool &flag);
    void setPin(uint8_t pin);
    inline uint8_t getPin() { return pin; };
    inline GPIO_TypeDef *getPort() const { return port; }
    inline uint16_t getPinMask() const { return mask; }
 protected:
    uint16_t id;
Author	SHA1	Message	Date
DashyFox	fc1a3bacef	upd	2026-03-11 16:57:55 +03:00
DashyFox	8a0d7f8dba	carrierPauseIfIdle/carrierResume	2026-02-06 16:06:23 +03:00
DashyFox	d1c84ba18a	no grammar fix	2025-10-17 17:28:01 +03:00
DashyFox	e9c568aed2	grammar fix	2025-10-17 17:25:09 +03:00
DashyFox	7bf71d1d52	calculateSendTime (need to fix)	2025-09-05 18:24:19 +03:00
DashyFox	38f3ecac3a	isBusy	2025-08-25 13:01:58 +03:00
DashyFox	dec8467280	max pack	2025-08-22 15:33:19 +03:00
DashyFox	bc9563fbb5	isReceive type	2025-05-23 11:43:51 +03:00
DashyFox	021e1e290d	fix isRX flag	2025-05-22 12:08:22 +03:00
DashyFox	89d14919c9	fix isRecive	2025-03-12 16:15:35 +03:00
DashyFox	403b8e6850	isRecive fix	2025-03-12 15:38:33 +03:00
DashyFox	d0c3138c52	Merge pull request #6 from Show-maket/STM32-opti-test Stm32 opti test	2025-03-06 17:07:13 +03:00
DashyFox	2d839d3ff8	HardwareTimer auto set support	2025-03-06 17:05:37 +03:00
DashyFox	6ba8fdffe4	auto begin	2025-02-25 18:05:10 +03:00
DashyFox	aa0b478229	faster for each	2025-02-25 15:17:09 +03:00
DashyFox	277985f79a	update ir adress space	2025-01-30 16:17:45 +03:00
DashyFox	444b84c313	hide test prints	2025-01-28 17:43:46 +03:00
DashyFox	2db1ef7805	test	2025-01-28 12:59:53 +03:00
DashyFox	1353ab6f75	constexpr IR_ResponseDelay	2025-01-28 12:59:42 +03:00