/* 

Red = Ard Pin 10
White = Ard Pin 11
Green = Ard Pin 12

DHT11() is disabled

 Version 1.2 with DHT11 RH, DS18B20 & Temp & secret voltmeter
 Version 1.3 with 7-segment testing, blink 5 times
 
 Original sketch from Paul Electronics 7-segment shift register posting
 RTC libraries from http://jeelabs.net/projects/cafe/wiki/RTClib
 Setting realtime clock on-compile was from Ladyada.net
 
 Pin assignment on the 74595 to 7-segment common cathode as follows :-
 
 QA - a
 QB - b
 QC - c
 QD - d
 QE - e
 QF - f
 QG - g
 
 pin 3 & 8 are common cathode
 resistors used is 220R
  
 Stanley Seow
 [email protected]
 
 */

#include <Wire.h>                // i2c wire libraries for RTC
#include "RTClib.h"              // RTC libraries
                                 // define 74595 pins
const int  g_pinData = 10;       // SI  (Pin 14 on 74595) Red wire
const int  g_pinCommLatch = 11;  // RCK (Pin 12 on 74595) White wire
const int  g_pinClock = 12;      // SCK (Pin 11 on 74595) Green wire
const int  ledPin = 13;          // for blinking every 1/2 seconds

//int temp = 0;
//int humid = 0;
//int volt = 0;

RTC_DS1307 RTC;                  // define RTC variables

byte g_digits [10];             // Definitions of the 7-bit values for displaying digits

int g_numberToDisplay = 0;      // default number being displayed, 0 

const int g_registers = 6;      // Number of shift registers in use, 4

byte g_registerArray [g_registers]; // Array of numbers to pass to shift registers

// Begin setup() functions //

void setup()
{
  
   
  
   // I2C RTC Setup
   Wire.begin();
   RTC.begin();
   
  /*  Only set the time on compile if the RTC is not running...
  This is used to set the current time from the computer clock
  
  if ( !RTC.isrunning()) {
    Serial.println("RTC is NOT running!");
    // following line sets the RTC to the date & time this sketch was compiled
    RTC.adjust(DateTime(__DATE__, __TIME__));
  }
  */

  pinMode (g_pinCommLatch, OUTPUT);       // define 74595 pins as output
  pinMode (g_pinClock, OUTPUT);           // define 74595 pins as output
  pinMode (g_pinData, OUTPUT);            // define 74595 pins as output
  pinMode (ledPin, OUTPUT);               // define LED pins as output
  
  Serial.begin (9600);                    // optional, turn on serial monitoring for debugging

  // Setup 7 segment display for number 0 to 9 and other characters
  
  // a - top bar
  // b - top right
  // c - bottom right
  // d - bottom bar
  // e - bottom left
  // f - top right
  // g - middle bar
  
  int a = 1, b = 2, c = 4, d = 8, e = 16, f = 32, g = 64;

  g_digits [0] = a + b + c + d + e + f;
  g_digits [1] = b + c;
  g_digits [2] = a + b + g + e + d;
  g_digits [3] = a + b + g + c + d;
  g_digits [4] = f + g + b + c;
  g_digits [5] = a + f + g + c + d;
  g_digits [6] = a + f + g + c + d + e;
  g_digits [7] = a + b + c;
  g_digits [8] = a + b + c + d + e + f + g;
  g_digits [9] = a + b + c + d + g + f;
  g_digits [90] = a + b + g + f;           // Degree dot
  g_digits [91] = a + f + e + d;           // Capital C
  g_digits [92] = e + g;                   //  r, 80
  g_digits [93] = f + e + g + c;           //  h, 116
  
  g_digits [99] = 0;
  
  // 7-segment testing... blink 4 times
  for (int i=0;i<7;i++) {
  
    g_registerArray [0] = g_digits [8];
    g_registerArray [1] = g_digits [8];
    g_registerArray [2] = g_digits [8];
    g_registerArray [3] = g_digits [8];
    g_registerArray [4] = g_digits [8];
    g_registerArray [5] = g_digits [8];
    sendSerialData (g_registers, g_registerArray);
    delay(300);

    g_registerArray [0] = g_digits [99];
    g_registerArray [1] = g_digits [99];
    g_registerArray [2] = g_digits [99];
    g_registerArray [3] = g_digits [99];
    g_registerArray [4] = g_digits [99];
    g_registerArray [5] = g_digits [99];
   
   
    sendSerialData (g_registers, g_registerArray);
    delay(300);
     
  }
  
    
  
} // End of setup() //

// Simple function to send serial data to one or more shift registers by iterating backwards through an array.
// Although g_registers exists, they may not all be being used, hence the input parameter.


  void sendSerialData (byte registerCount, byte *pValueArray) {
  // Signal to the 595s to listen for data
  digitalWrite (g_pinCommLatch, LOW);

  for (byte reg = registerCount; reg > 0; reg--)

  
  {
    byte value = pValueArray [reg - 1];
 
    for (byte bitMask = 128; bitMask > 0; bitMask >>= 1)
    {
      digitalWrite (g_pinClock, LOW);
      digitalWrite (g_pinData, value & bitMask ? HIGH : LOW);
      digitalWrite (g_pinClock, HIGH);
    }
  }
  // Signal to the 595s that I'm done sending
  digitalWrite (g_pinCommLatch, HIGH);
}  // sendSerialData


// Fucntion to read Arduino hidden voltmeter

// ======================  Main loop() ======================= 

void loop()
{
  int hour,minute,sec,disp = 0;

   DateTime now = RTC.now();  // Get current time & date

   hour = now.hour();         // break down time to hour
   minute = now.minute();     // break down time to minute
   sec = now.second();        // break down time to second
  
  /* Serial output debugging for the date & time 
  
   Serial.print(now.year(), DEC);
   Serial.print('/');
   Serial.print(now.month(), DEC);
   Serial.print('/');
   Serial.print(now.day(), DEC);
   Serial.print(' ');
 */
 
   Serial.print(hour);
   Serial.print(':');
   Serial.print(minute);
   Serial.print(':');    
   Serial.print(sec);
   Serial.println();
  
  
  // Push the hour 2 digits to the left by multiplying 100
  
  disp = hour*1000   ;
  g_numberToDisplay = disp;

   
  // Push the numbers to the four digits
  
  if (g_numberToDisplay < 10)
  {
    g_registerArray [0] = g_digits [0];
    g_registerArray [1] = g_digits [0];
    g_registerArray [2] = g_digits [0];
    g_registerArray [3] = g_digits [0];
    g_registerArray [4] = g_digits [0];
    g_registerArray [5] = g_digits [g_numberToDisplay];
  }
  else if (g_numberToDisplay < 100)
  {
    g_registerArray [0] = g_digits [0];
    g_registerArray [1] = g_digits [0];
    g_registerArray [2] = g_digits [0];
    g_registerArray [3] = g_digits [0];
    g_registerArray [4] = g_digits [g_numberToDisplay / 10];
    g_registerArray [5] = g_digits [g_numberToDisplay % 10];
  }
  else if (g_numberToDisplay < 1000)
  {
    g_registerArray [0] = g_digits [0];
    g_registerArray [1] = g_digits [0];
    g_registerArray [2] = g_digits [0];
    g_registerArray [3] = g_digits [g_numberToDisplay / 100];
    g_registerArray [4] = g_digits [(g_numberToDisplay % 100) / 10];
    g_registerArray [5] = g_digits [g_numberToDisplay % 10];
  }
  else if (g_numberToDisplay < 10000)
  {
    g_registerArray [0] = g_digits [0];
    g_registerArray [1] = g_digits [0];
    g_registerArray [2] = g_digits [g_numberToDisplay / 1000];
    g_registerArray [3] = g_digits [(g_numberToDisplay % 1000) / 100];
    g_registerArray [4] = g_digits [(g_numberToDisplay % 100) / 10];
    g_registerArray [5] = g_digits [g_numberToDisplay % 10];
  }
  else if (g_numberToDisplay < 10000)
  {
    g_registerArray [0] = g_digits [0];
    g_registerArray [1] = g_digits [g_numberToDisplay / 100000];
    g_registerArray [2] = g_digits [(g_numberToDisplay % 10000)/ 1000];
    g_registerArray [3] = g_digits [(g_numberToDisplay % 1000) / 100];
    g_registerArray [4] = g_digits [(g_numberToDisplay % 100) / 10];
    g_registerArray [5] = g_digits [g_numberToDisplay % 10];
  
  }
    else
  {
    g_registerArray [0] = g_digits [g_numberToDisplay  / 100000];
    g_registerArray [1] = g_digits [(g_numberToDisplay % 100000)/ 10000];
    g_registerArray [2] = g_digits [(g_numberToDisplay % 10000)/ 1000];
    g_registerArray [3] = g_digits [(g_numberToDisplay % 1000) / 100];
    g_registerArray [4] = g_digits [(g_numberToDisplay % 100) / 10];
    g_registerArray [5] = g_digits [g_numberToDisplay % 10];
  }
    sendSerialData (g_registers, g_registerArray);
     
    
  {
  
  //Blink the LED on pin 13 every seconds
  digitalWrite(ledPin,HIGH);
  delay(500);
  digitalWrite(ledPin,LOW);
  delay(500);
  
}
}
// end of loop