Delete Dec_Dir_and_Fade.ino
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// Production 17 Function DCC Decoder Dec_Dir_and_Fade.ino
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// Version 6.0 Geoff Bunza 2014,2015,2016,2017,2018
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// Now works with both short and long DCC Addesses
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// LED control is dependent on direction of travel and Fade can be added
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// ******** UNLESS YOU WANT ALL CV'S RESET UPON EVERY POWER UP
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// ******** AFTER THE INITIAL DECODER LOAD REMOVE THE "//" IN THE FOOLOWING LINE!!
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//#define DECODER_LOADED
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#include <NmraDcc.h>
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int tim_delay = 500;
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#define numleds 17
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byte ledpins [] = {3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19}; //Defines all possible LED pins
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// IMPORTANT:
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// The following list defines how each of the 17 function pins operate:
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// a 0 allows for normal On/Off control with fade on and fade off
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// a 1 allows for normal control when the decoder sees a forward speed setting, reverse turns the LED off
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// a 2 allows for normal control when the decoder sees a reverse speed setting, forward turns the LED off
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byte led_direction [] = {0,1,2,0,1,1,1,1,2,2,2,1,1,1,2,0,0}; //0=On/Off, 1=On Forward, 2=On Reverse
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boolean led_last_state [] = {false,false,false,false,false,false,false,false,false,false,false,false,false,false,false,false,false}; //last state of led
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boolean Last_Function_State[] = {false,false,false,false,false,false,false,false,false,false,false,false,false,false,false,false,false}; //These hold the last Fx assignments
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uint8_t Decoder_direction = DCC_DIR_FWD;
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uint8_t Last_Decoder_direction = 0;
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int fade_time = 170;
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const int FunctionPin0 = 3;
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const int FunctionPin1 = 4;
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const int FunctionPin2 = 5;
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const int FunctionPin3 = 6;
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const int FunctionPin4 = 7;
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const int FunctionPin5 = 8;
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const int FunctionPin6 = 9;
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const int FunctionPin7 = 10;
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const int FunctionPin8 = 11;
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const int FunctionPin9 = 12;
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const int FunctionPin10 = 13;
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const int FunctionPin11 = 14; //A0
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const int FunctionPin12 = 15; //A1
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const int FunctionPin13 = 16; //A2
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const int FunctionPin14 = 17; //A3
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const int FunctionPin15 = 18; //A4
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const int FunctionPin16 = 19; //A5
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NmraDcc Dcc ;
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DCC_MSG Packet ;
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uint8_t CV_DECODER_MASTER_RESET = 120;
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struct CVPair
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{
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uint16_t CV;
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uint8_t Value;
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};
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#define This_Decoder_Address 24
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CVPair FactoryDefaultCVs [] =
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{
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{CV_MULTIFUNCTION_PRIMARY_ADDRESS, This_Decoder_Address&0x7F },
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// These two CVs define the Long DCC Address
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{CV_MULTIFUNCTION_EXTENDED_ADDRESS_MSB, ((This_Decoder_Address>>8)&0x7F)+192 },
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{CV_MULTIFUNCTION_EXTENDED_ADDRESS_LSB, This_Decoder_Address&0xFF },
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// ONLY uncomment 1 CV_29_CONFIG line below as approprate DEFAULT IS SHORT ADDRESS
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// {CV_29_CONFIG, 0}, // Short Address 14 Speed Steps
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{CV_29_CONFIG, CV29_F0_LOCATION}, // Short Address 28/128 Speed Steps
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// {CV_29_CONFIG, CV29_EXT_ADDRESSING | CV29_F0_LOCATION}, // Long Address 28/128 Speed Steps
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{CV_DECODER_MASTER_RESET, 0},
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};
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uint8_t FactoryDefaultCVIndex = 0;
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void notifyCVResetFactoryDefault()
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{
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// Make FactoryDefaultCVIndex non-zero and equal to num CV's to be reset
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// to flag to the loop() function that a reset to Factory Defaults needs to be done
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FactoryDefaultCVIndex = sizeof(FactoryDefaultCVs)/sizeof(CVPair);
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};
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void setup()
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{
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//Serial.begin(115200);
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// initialize the digital pins as an outputs
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for (int i=0; i< numleds; i++) {
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pinMode(ledpins[i], OUTPUT);
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digitalWrite(ledpins[i], LOW);
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}
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for (int i=0; i< numleds; i++) {
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digitalWrite(ledpins[i], HIGH);
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delay (tim_delay/10);
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}
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delay( tim_delay);
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for (int i=0; i< numleds; i++) {
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digitalWrite(ledpins[i], LOW);
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delay (tim_delay/10);
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}
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delay( tim_delay);
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#if defined(DECODER_LOADED)
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if ( Dcc.getCV(CV_DECODER_MASTER_RESET)== CV_DECODER_MASTER_RESET )
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#endif
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{
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for (int j=0; j < FactoryDefaultCVIndex; j++ )
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Dcc.setCV( FactoryDefaultCVs[j].CV, FactoryDefaultCVs[j].Value);
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digitalWrite(ledpins[14], 1);
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delay (1000);
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digitalWrite(ledpins[14], 0);
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}
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// Setup which External Interrupt, the Pin it's associated with that we're using and enable the Pull-Up
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Dcc.pin(0, 2, 0);
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// Call the main DCC Init function to enable the DCC Receiver
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Dcc.init( MAN_ID_DIY, 600, FLAGS_MY_ADDRESS_ONLY, 0 );
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}
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void loop()
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{
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// You MUST call the NmraDcc.process() method frequently from the Arduino loop() function for correct library operation
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Dcc.process();
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}
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void notifyDccFunc( uint16_t Addr, DCC_ADDR_TYPE AddrType, FN_GROUP FuncGrp, uint8_t FuncState) {
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int f_index;
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switch (FuncGrp) {
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case FN_0_4: //Function Group 1 F0 F4 F3 F2 F1
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exec_function( 0, (FuncState & FN_BIT_00)>>4 );
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exec_function( 1, (FuncState & FN_BIT_01));
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exec_function( 2, (FuncState & FN_BIT_02)>>1);
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exec_function( 3, (FuncState & FN_BIT_03)>>2 );
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exec_function( 4, (FuncState & FN_BIT_04)>>3 );
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break;
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case FN_5_8: //Function Group 1 S FFFF == 1 F8 F7 F6 F5 & == 0 F12 F11 F10 F9 F8
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exec_function( 5, (FuncState & FN_BIT_05));
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exec_function( 6, (FuncState & FN_BIT_06)>>1 );
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exec_function( 7, (FuncState & FN_BIT_07)>>2 );
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exec_function( 8, (FuncState & FN_BIT_08)>>3 );
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break;
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case FN_9_12:
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exec_function( 9, (FuncState & FN_BIT_09));
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exec_function( 10,(FuncState & FN_BIT_10)>>1 );
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exec_function( 11,(FuncState & FN_BIT_11)>>2 );
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exec_function( 12,(FuncState & FN_BIT_12)>>3 );
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break;
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case FN_13_20: //Function Group 2 FuncState == F20-F13 Function Control
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exec_function( 13, (FuncState & FN_BIT_13));
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exec_function( 14, (FuncState & FN_BIT_14)>>1 );
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exec_function( 15, (FuncState & FN_BIT_15)>>2 );
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exec_function( 16, (FuncState & FN_BIT_16)>>3 );
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break;
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}
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}
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void exec_function (int f_index, int FuncState) {
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if ((FuncState==1) && (!Last_Function_State[f_index])) {
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Last_Function_State[f_index] = true;
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Set_LED (f_index,true);
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}
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else if ((FuncState==0) && Last_Function_State[f_index]) {
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Last_Function_State[f_index] = false;
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Set_LED (f_index,false);
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}
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}
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void notifyDccSpeed( uint16_t Addr, DCC_ADDR_TYPE AddrType, uint8_t Speed, DCC_DIRECTION ForwardDir, DCC_SPEED_STEPS SpeedSteps ) {
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Last_Decoder_direction = Decoder_direction;
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Decoder_direction = ForwardDir;
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if ( Decoder_direction==Last_Decoder_direction) return;
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for (int i=0; i<numleds; i++) {
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if (Decoder_direction!=0 && led_direction[i]==1 && Last_Function_State[i] && led_last_state[i]==false ) Switch_LED (i);
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if (Decoder_direction!=0 && led_direction[i]==2 && Last_Function_State[i] && led_last_state[i]==true ) Switch_LED (i);
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if (Decoder_direction==0 && led_direction[i]==2 && Last_Function_State[i] && led_last_state[i]==false ) Switch_LED (i);
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if (Decoder_direction==0 && led_direction[i]==1 && Last_Function_State[i] && led_last_state[i]==true ) Switch_LED (i);
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}
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}
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void Set_LED (int Function, boolean led_state) {
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boolean start_state = !led_state;
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boolean end_state = led_state;
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switch (led_direction[Function]) {
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case 0: //0=On/Off
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if (led_last_state[Function] == led_state) return;
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Switch_LED (Function);
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break;
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case 1: //1=On Forward
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if (Decoder_direction!=0) {
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if (led_last_state[Function] == led_state) return;
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Switch_LED (Function);
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}
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break;
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case 2: //2=On Reverse
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if (Decoder_direction==0) {
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if (led_last_state[Function] == led_state) return;
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Switch_LED (Function);
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}
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break;
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default:
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break;
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}
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}
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void Switch_LED (int Function) {
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float time_fraction;
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int del_temp;
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boolean start_state = led_last_state[Function];
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boolean end_state = !led_last_state[Function];
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for (int loop_time=0; loop_time<fade_time; loop_time++) {
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time_fraction = (float (loop_time))/(float (fade_time));
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digitalWrite (ledpins[Function], start_state);
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del_temp = 1000 - (1000.*time_fraction);
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if (del_temp<0) del_temp=0;
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delayMicroseconds (del_temp);
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digitalWrite (ledpins[Function], end_state);
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delayMicroseconds (1000.*time_fraction);
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}
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led_last_state[Function] = end_state;
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}
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