Refactor wiegand to 32-bit

Refactor wiegand from 64-bit to 32-bit while keeping full 34-bit support

tasmota/xsns_82_wiegand.ino

@@ -40,6 +40,8 @@
  * 20220215
  *  - fix 34-bit size parity chk
  *  - fix 64-bit representation after removal of %llu support (Tasmota does not support 64-bit decimal output specifier (%llu) saving 60k code)
+ *  - change internal rfid size from uint64_t to uint32_t
+ *  - limited max amount of kaypad presses to a 32-bit number (at least 999999999)
  * ---
  * 20201101
  *  - fix for #11047 Wiegand 26/34 missed some key press if they are press at normal speed
@@ -106,23 +108,21 @@ class Wiegand {
     #if (DEV_WIEGAND_TEST_MODE!=1)
     private:
     #endif //(DEV_WIEGAND_TEST_MODE==1)
-    uint64_t CheckAndConvertRfid(uint64_t,uint16_t);
+    uint32_t CheckAndConvertRfid(uint64_t,uint16_t);
     uint8_t CalculateParities(uint64_t, int);
     bool WiegandConversion (uint64_t , uint16_t );
-    void setOutputFormat(void); // fix output HEX format
     void HandleKeyPad(void); //handle one tag for multi key strokes
 
-
     static void handleD0Interrupt(void);
     static void handleD1Interrupt(void);
     static void handleDxInterrupt(int in); // fix #11047
     static void ClearRFIDBuffer(int);
 
-    uint64_t rfid;
+    uint32_t rfid;
     uint32_t tagSize;
     const char* outFormat;
-    uint64_t mqttRFIDKeypadBuffer;
-    uint64_t webRFIDKeypadBuffer;
+    uint32_t mqttRFIDKeypadBuffer;
+    uint32_t webRFIDKeypadBuffer;
 
     static volatile uint64_t rfidBuffer;
     static volatile uint16_t bitCount;
@@ -149,15 +149,14 @@ volatile bool Wiegand::CodeComplete;
 volatile RFID_store Wiegand::rfid_found[WIEGAND_RFID_ARRAY_SIZE];
 volatile int Wiegand::currentFoundRFIDcount;
 
-
-
 void IRAM_ATTR Wiegand::ClearRFIDBuffer(int endIndex = WIEGAND_RFID_ARRAY_SIZE) {
   currentFoundRFIDcount = WIEGAND_RFID_ARRAY_SIZE - endIndex; // clear all buffers
-    for (int i= 0; i < endIndex; i++) {
+  for (uint32_t i = 0; i < endIndex; i++) {
     rfid_found[i].RFID=0;
     rfid_found[i].bitCount=0;
   }
 }
+
 void IRAM_ATTR Wiegand::handleD1Interrupt() {  // Receive a 1 bit. (D0=high & D1=low)
   handleDxInterrupt(1);
 }
@@ -167,8 +166,8 @@ void IRAM_ATTR Wiegand::handleD0Interrupt() {  // Receive a 0 bit. (D0=low & D1=
 }
 
 void IRAM_ATTR Wiegand::handleDxInterrupt(int in) {
-  unsigned long curTime = micros();  // to be sure I will use micros() instead of millis() overflow is handle by using the minus operator to compare
-  unsigned long diffTime= curTime - lastFoundTime;
+  uint32_t curTime = micros();  // to be sure I will use micros() instead of millis() overflow is handle by using the minus operator to compare
+  uint32_t diffTime = curTime - lastFoundTime;
   if ((diffTime > CodeGapTime) && (bitCount > 0)) {
     // previous RFID tag (key pad numer)is complete. Will be detected by the code ending gap
     // one bit will take the time of impulse_time + impulse_gap_time. it (bitTime) will be recalculated each time an impulse is detected
@@ -247,7 +246,7 @@ void Wiegand::Init() {
 #endif  // DEV_WIEGAND_TEST_MODE>0
 }
 
-uint64_t Wiegand::CheckAndConvertRfid(uint64_t rfidIn, uint16_t bitCount) {
+uint32_t Wiegand::CheckAndConvertRfid(uint64_t rfidIn, uint16_t bitCount) {
   uint8_t evenParityBit = 0;
   uint8_t oddParityBit = (uint8_t) (rfidIn & 0x1);  // Last bit = odd parity
   uint8_t calcParity = 0;
@@ -277,8 +276,8 @@ uint64_t Wiegand::CheckAndConvertRfid(uint64_t rfidIn, uint16_t bitCount) {
   }
   calcParity = CalculateParities(rfidIn, bitCount);    // Check result on http://www.ccdesignworks.com/wiegand_calc.htm with raw tag as input
   if (calcParity != (evenParityBit | oddParityBit)) {  // Parity bit is wrong
+    AddLog(LOG_LEVEL_DEBUG, PSTR("WIE: %_X parity error"), &rfidIn);  // Print up to uint64_t
     rfidIn=0;
-    AddLog(LOG_LEVEL_DEBUG, PSTR("WIE: %_X parity error"), &rfidIn);
   }
 #if (DEV_WIEGAND_TEST_MODE)>0
   AddLog(LOG_LEVEL_INFO, PSTR("WIE: even (left) parity: %u "), (evenParityBit>>7));
@@ -286,7 +285,7 @@ uint64_t Wiegand::CheckAndConvertRfid(uint64_t rfidIn, uint16_t bitCount) {
   AddLog(LOG_LEVEL_INFO, PSTR("WIE: odd (right) parity: %u "), oddParityBit);
   AddLog(LOG_LEVEL_INFO, PSTR("WIE: odd (calc) parity: %u "), (calcParity & 0x01));
 #endif  // DEV_WIEGAND_TEST_MODE>0
-  return rfidIn;
+  return (uint32_t)rfidIn;
 }
 
 uint8_t Wiegand::CalculateParities(uint64_t tagWithoutParities, int tag_size = 26) {
@@ -299,7 +298,7 @@ uint8_t Wiegand::CalculateParities(uint64_t tagWithoutParities, int tag_size=26)
   tag_size -= 2;
   if (tag_size <= 0) { return retValue; }      // Prohibit div zero exception and other wrong inputs
   uint8_t parity = 1;                          // Check for odd parity on LSB
-  for (uint8_t i = 0; i < (tag_size / 2); i++) {
+  for (uint32_t i = 0; i < (tag_size / 2); i++) {
     parity ^= (tagWithoutParities & 1);
     tagWithoutParities >>= 1;
   }
@@ -318,7 +317,7 @@ uint8_t Wiegand::CalculateParities(uint64_t tagWithoutParities, int tag_size=26)
 bool Wiegand::WiegandConversion (uint64_t rfidBuffer, uint16_t bitCount) {
   bool bRet = false;
 #if (DEV_WIEGAND_TEST_MODE)>0
-    AddLog(LOG_LEVEL_INFO, PSTR("WIE: Raw tag %llu, Bit count %u"), rfidBuffer, bitCount);
+  AddLog(LOG_LEVEL_INFO, PSTR("WIE: Raw tag %_X, Bit count %u"), &rfidBuffer, bitCount);  // Print up to uint64_t
 #endif  // DEV_WIEGAND_TEST_MODE>0
   if ((24 == bitCount) || (26 == bitCount) || (32 == bitCount) || (34 == bitCount)) {
     // 24, 26, 32, 34-bit Wiegand codes
@@ -328,7 +327,7 @@ bool Wiegand::WiegandConversion (uint64_t rfidBuffer, uint16_t bitCount) {
   }
   else if (4 == bitCount) {
     // 4-bit Wiegand codes for keypads
-      rfid = (int)(rfidBuffer & 0x0000000F);
+    rfid = (uint32_t)(rfidBuffer & 0x0000000F);
     tagSize = bitCount;
     bRet = true;
   }
@@ -339,7 +338,7 @@ bool Wiegand::WiegandConversion (uint64_t rfidBuffer, uint16_t bitCount) {
     char highNibble = (rfidBuffer & 0xf0) >>4;
     char lowNibble = (rfidBuffer & 0x0f);
     if (lowNibble == (~highNibble & 0x0f)) {   // Check if low nibble matches the "NOT" of high nibble.
-        rfid = (int)(lowNibble);
+      rfid = (uint32_t)(lowNibble);
       bRet = true;
     } else {
       bRet = false;
@@ -351,17 +350,11 @@ bool Wiegand::WiegandConversion (uint64_t rfidBuffer, uint16_t bitCount) {
     bRet = false;
   }
 #if (DEV_WIEGAND_TEST_MODE)>0
-  AddLog(LOG_LEVEL_INFO, PSTR("WIE: Tag out %llu, tag size %u "), rfid, tagSize);
+  AddLog(LOG_LEVEL_INFO, PSTR("WIE: Tag out %u, tag size %u "), rfid, tagSize);
 #endif  // DEV_WIEGAND_TEST_MODE>0
   return bRet;
 }
 
-void Wiegand::setOutputFormat(void)
-{
-  if (GetOption(WIEGAND_OPTION_HEX) == 0)  { outFormat = "u";  }
-  else  {  outFormat = "X" WIEGAND_OPTION_HEX_POSTFIX ;  }
-}
-
 void Wiegand::HandleKeyPad(void) { // will be called if a valid key pad input was recognized
   if (GetOption(WIEGAND_OPTION_KEYPAD_TO_TAG) == 0) { // handle all key pad inputs as ONE Tag until # is recognized
     if ((tagSize == 4) || (tagSize == 8)) {
@@ -386,24 +379,19 @@ void Wiegand::HandleKeyPad(void) { // will be called if a valid key pad input wa
 }
 
 void Wiegand::ScanForTag() {
-  unsigned long startTime = micros();
+  uint32_t startTime = micros();
   handleDxInterrupt(3);
   if (currentFoundRFIDcount > 0) {
-    unsigned int lastFoundRFIDcount = currentFoundRFIDcount;
+    uint32_t lastFoundRFIDcount = currentFoundRFIDcount;
 #if (DEV_WIEGAND_TEST_MODE)>0
-    AddLog(LOG_LEVEL_INFO, PSTR("WIE: ScanForTag(). bitTime: %0lu lastFoundTime: %0lu RFIDS in buffer: %lu"), bitTime, lastFoundTime, currentFoundRFIDcount);
+    AddLog(LOG_LEVEL_INFO, PSTR("WIE: ScanForTag(). bitTime: %u lastFoundTime: %u RFIDS in buffer: %u"), bitTime, lastFoundTime, currentFoundRFIDcount);
 #endif
-    // format MQTT output
-//    setOutputFormat();
-//    char sFormat[50];
-//    snprintf( sFormat, 50, PSTR(",\"Wiegand\":{\"UID\":%%0ll%s,\"" D_JSON_SIZE "\":%%%s}}"), outFormat, outFormat);
-    for (int i= 0; i < WIEGAND_RFID_ARRAY_SIZE; i++)
-    {
+    for (uint32_t i = 0; i < WIEGAND_RFID_ARRAY_SIZE; i++) {
   	  if (rfid_found[i].RFID != 0 || (rfid_found[i].RFID == 0 && i == 0)) {
-        uint64_t oldTag = rfid;
+        uint32_t oldTag = rfid;
         bool validKey =  WiegandConversion(rfid_found[i].RFID, rfid_found[i].bitCount);
 #if (DEV_WIEGAND_TEST_MODE)>0
-        AddLog(LOG_LEVEL_INFO, PSTR("WIE: ValidKey: %d Previous tag %llu"), validKey, oldTag);
+        AddLog(LOG_LEVEL_INFO, PSTR("WIE: ValidKey %d, Previous tag %u"), validKey, oldTag);
 #endif  // DEV_WIEGAND_TEST_MODE>0
         if (validKey) {  // Only in case of valid key do action. Issue#10585
           HandleKeyPad();  //support one tag for multi key input
@@ -411,13 +399,13 @@ void Wiegand::ScanForTag() {
             if (oldTag == rfid) {
               AddLog(LOG_LEVEL_DEBUG, PSTR("WIE: Old tag"));
             }
-//            ResponseTime_P(sFormat, rfid, tagSize);
-//          Tasmota does not support 64-bit decimal output specifier (%llu) saving 60k code
+            ResponseTime_P(PSTR(",\"Wiegand\":{\"UID\":"));
             if (GetOption(WIEGAND_OPTION_HEX) == 0) {
-              ResponseTime_P(PSTR(",\"Wiegand\":{\"UID\":%lu,\"" D_JSON_SIZE "\":%d}}"), (uint32_t)rfid, tagSize);
+              ResponseAppend_P(PSTR("%u"), rfid);
             } else {
-              ResponseTime_P(PSTR(",\"Wiegand\":{\"UID\":\"%1_X" WIEGAND_OPTION_HEX_POSTFIX "\",\"" D_JSON_SIZE "\":%d}}"), &rfid, tagSize);
+              ResponseAppend_P(PSTR("\"%X" WIEGAND_OPTION_HEX_POSTFIX "\""), rfid);
             }
+            ResponseAppend_P(PSTR(",\"" D_JSON_SIZE "\":%d}}"), tagSize);
             MqttPublishTeleSensor();
           }
         }
@@ -426,33 +414,29 @@ void Wiegand::ScanForTag() {
     if (currentFoundRFIDcount > lastFoundRFIDcount) {
       // if that happens: we need to move the id found during the loop to top of the array
       // and correct the currentFoundRFIDcount
-      AddLog(LOG_LEVEL_INFO, PSTR("WIE: ScanForTag() %lu tags added while working on buffer"), (currentFoundRFIDcount-lastFoundRFIDcount));
+      AddLog(LOG_LEVEL_INFO, PSTR("WIE: ScanForTag() %u tags added while working on buffer"), (currentFoundRFIDcount - lastFoundRFIDcount));
     }
     ClearRFIDBuffer(); //reset array
 #if (DEV_WIEGAND_TEST_MODE)>0
-    AddLog(LOG_LEVEL_INFO, PSTR("WIE: ScanForTag() time elapsed %lu"), (micros() - startTime));
+    AddLog(LOG_LEVEL_INFO, PSTR("WIE: ScanForTag() time elapsed %u"), (micros() - startTime));
 #endif
   }
-
 }
 
 #ifdef USE_WEBSERVER
 void Wiegand::Show(void) {
-//    setOutputFormat();
-//    char sFormat [30];
-//    snprintf( sFormat, 30,PSTR("{s}Wiegand UID{m}%%ll%s {e}"), outFormat);
-//    if (tagSize>0) { WSContentSend_PD(sFormat, rfid); }
-//    else { WSContentSend_PD(sFormat, webRFIDKeypadBuffer); }
-//  Tasmota does not support 64-bit decimal output specifier (%llu) saving 60k code
+  WSContentSend_P(PSTR("{s}Wiegand UID{m}"));
   if (GetOption(WIEGAND_OPTION_HEX) == 0) {
-      WSContentSend_P(PSTR("{s}Wiegand UID{m}%lu{e}"), (tagSize>0) ? (uint32_t)rfid : (uint32_t)webRFIDKeypadBuffer);
+    WSContentSend_P(PSTR("%u"), (tagSize > 0) ? rfid : webRFIDKeypadBuffer);
   } else {
-      WSContentSend_P(PSTR("{s}Wiegand UID{m}%1_X" WIEGAND_OPTION_HEX_POSTFIX "{e}"), (tagSize>0) ? &rfid : &webRFIDKeypadBuffer);
+    WSContentSend_P(PSTR("%X" WIEGAND_OPTION_HEX_POSTFIX), (tagSize > 0) ? rfid : webRFIDKeypadBuffer);
   }
-    #if (DEV_WIEGAND_TEST_MODE)>0
-    AddLog(LOG_LEVEL_INFO, PSTR("WIE: Tag %llu, Bits %u"), rfid, bitCount);
-    #endif  // DEV_WIEGAND_TEST_MODE>0
+  WSContentSend_P(PSTR("{e}"));
 
+
+#if (DEV_WIEGAND_TEST_MODE)>0
+  AddLog(LOG_LEVEL_INFO, PSTR("WIE: Tag %u, Bits %u"), rfid, bitCount);
+#endif  // DEV_WIEGAND_TEST_MODE>0
 }
 #endif  // USE_WEBSERVER