370 lines
14 KiB
C++
370 lines
14 KiB
C++
#include <Arduino.h>
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#include "TimerOne.h"
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#include <EEPROM.h>
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#define BAUD 9600
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//TLC5940NT pin definitions
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#define VPRG 2
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#define SIN 11
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#define SCLK 13
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#define XLAT 4
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#define BLANK 5
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#define DCPRG 6
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#define GSCLK 7
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#define id 0
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#define first_flash true
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// start reading from the first byte (address 0) of the EEPROM
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int address = 300;
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int vuelta = 0;
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#define intensidad 252 //0 - 255
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const byte remap[7][5] = { //Mapeo de los leds
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{0,7,18,25,36},
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{1,8,19,26,37},
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{2,9,20,27,38},
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{3,10,21,32,39},
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{4,11,22,33,40},
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{5,16,23,34,41},
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{6,17,24,35,42},
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};
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int modo= 0;
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byte numero[10][7] = { { B01110, B10001, B10011, B10101, B11001, B10001, B01110}, //48 = '0'
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{ B00100, B01100, B10100, B00100, B00100, B00100, B11111}, //49 = '1'
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{ B01110, B10001, B00001, B00110, B01000, B10000, B11111}, //50 = '2'
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{ B01110, B10001, B00001, B01110, B00001, B10001, B01110}, //51 = '3'
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{ B00010, B00110, B01010, B10010, B11111, B00010, B00010}, //52 = '4'
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{ B11111, B10000, B11110, B00001, B00001, B10001, B01110}, //53 = '5'
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{ B01110, B10001, B10000, B11110, B10001, B10001, B01110}, //54 = '6'
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{ B11111, B00001, B00010, B00100, B01000, B10000, B10000}, //55 = '7'
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{ B01110, B10001, B10001, B01110, B10001, B10001, B01110}, //56 = '8'
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{ B01110, B10001, B10001, B01111, B00001, B10001, B01110}, //57 = '9'
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};
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byte caracterA[13][7] = {{ B01110, B10001, B10001, B11111, B10001, B10001, B10001}, //65 = 'A'
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{ B11110, B10001, B10001, B11110, B10001, B10001, B11110}, //66 = 'B'
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{ B01110, B10001, B10000, B10000, B10000, B10001, B01110}, //67 = 'C'
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{ B11110, B10001, B10001, B10001, B10001, B10001, B11110}, //68 = 'D'
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{ B11111, B10000, B10000, B11110, B10000, B10000, B11111}, //69 = 'E'
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{ B11111, B10000, B10000, B11110, B10000, B10000, B10000}, //70 = 'F'
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{ B01110, B10001, B10000, B10111, B10001, B10001, B01110}, //71 = 'G'
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{ B10001, B10001, B10001, B11111, B10001, B10001, B10001}, //72 = 'H'
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{ B11111, B00100, B00100, B00100, B00100, B00100, B11111}, //73 = 'I'
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{ B00001, B00001, B00001, B00001, B10001, B10001, B01110}, //74 = 'J'
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{ B10001, B10010, B10100, B11000, B10100, B10010, B10001}, //75 = 'K'
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{ B10000, B10000, B10000, B10000, B10000, B10000, B11111}, //76 = 'L'
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{ B10001, B11011, B10101, B10001, B10001, B10001, B10001}, //77 = 'M'
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};
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byte caracterB[14][7] = {{ B10001, B11001, B10101, B10011, B10001, B10001, B10001}, //78 = 'N'
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{ B01110, B10001, B10001, B10001, B10001, B10001, B01110}, //79 = 'O'
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{ B11110, B10001, B10001, B11110, B10000, B10000, B10000}, //80 = 'P'
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{ B01110, B10001, B10001, B10001, B10101, B10101, B01110}, //81 = 'Q'
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{ B11110, B10001, B10001, B11110, B10100, B10010, B10001}, //82 = 'R'
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{ B01110, B10001, B10000, B01110, B00001, B10001, B01110}, //83 = 'S'
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{ B11111, B00100, B00100, B00100, B00100, B00100, B00100}, //84 = 'T'
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{ B10001, B10001, B10001, B10001, B10001, B10001, B01110}, //85 = 'U'
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{ B10001, B10001, B10001, B10001, B10001, B01010, B00100}, //86 = 'V'
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{ B10001, B10001, B10001, B10001, B10101, B10101, B01010}, //87 = 'W'
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{ B10001, B10001, B01010, B00100, B01010, B10001, B10001}, //88 = 'X'
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{ B10001, B10001, B01010, B00100, B00100, B00100, B00100}, //89 = 'Y'
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{ B11111, B00001, B00010, B00100, B01000, B10000, B11111}, //90 = 'Z'
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{ B10000, B10000, B10000, B10010, B01010, B00110, B11110}, //flecha = 35
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};
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byte espacio[7] = { B00000, B00000, B00000, B00000, B00000, B00000, B00000}; //32 = ' '
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//byte sonrisa[7] = { B00000, B01010, B01010, B00000, B10001, B01110, B00000}; //Sonrisa
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byte test[7] = { B11111, B11111, B11111, B11111, B11111, B11111, B11111};//0x01
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byte test1[7] = { B11111, B11111, B11111, B11111, B11111, B11111, B11111};//0x01
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// Holds the current colour level for each of the buttons
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int levelW[64] = {
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0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
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0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
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0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
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0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
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// Variables for interpreting the serial commands
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byte command[64] = {
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' ', ' ', 'B', 'E', 'N', 'V', 'I', 'N', 'G', 'U', 'D', 'E', 'S', ' ', ' ', ' ',
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' ', 'B', 'E', 'N', 'V', 'I', 'N', 'G', 'U', 'T', 'S', ' ', 'A', 'L', ' ', ' ',
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' ', ' ', 'C', 'I', 'B', 'E', 'R', 'N', 'A', 'R', 'I', 'U', 'M', ' ', ' ', ' ',
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' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' '};
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byte finish = 1;
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byte count = 0x00;
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boolean save=false;
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boolean sincro=false;
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boolean bloqueo=false;
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boolean update = false;
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unsigned long time=0;
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// Transfer a character out over hardware SPI
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char spi_transfer(volatile byte data)
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{
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SPDR = data; // Start the transmission
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while (!(SPSR & (1<<SPIF))) // Wait the end of the transmission
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{
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};
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return SPDR; // return the received byte
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}
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void timerIsr(){
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sei(); //Reenable global interrupts, otherwise serial commands will get dropped
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if(Serial.available()){
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byte val = Serial.read();
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if ((val=='\r')||(val=='\n'))
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{
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if(val=='\r')
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{
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Serial.write(val);
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count = 0x00;
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vuelta = 0x00;
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command[0] = ' ';
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bloqueo = false;
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save = true;
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}
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}
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#if id == 0
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else if ((val==' ')||((val<='9')&&(val>='0'))||((val<'N')&&(val>='A'))||((val<='Z')&&(val>='N'))||((val<'n')&&(val>='a'))||((val<='z')&&(val>='n')))
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{
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command[count] = val;
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count++;
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bloqueo = false;
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save = true;
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update = true;
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}
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#else
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else if (val== (id + 0x0F)) sincro = true;
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else if (sincro) {command[0] = val; bloqueo = false; sincro = false;}
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else Serial.write(val);
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#endif
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}
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// If the serial buffer is getting too close to full, keep executing the parsing until it falls below a given level
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// This might cause flicker, or even dropped messages, but it should prevent a crash.
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}
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void setup() {
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// Start the serial port
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Serial.begin(BAUD);
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delay(10);
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//Setup data directions, and set everything to the correct initial levels,
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// For TLC5940
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pinMode(VPRG, OUTPUT);
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pinMode(SIN, OUTPUT);
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pinMode(SCLK, OUTPUT);
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pinMode(XLAT, OUTPUT);
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pinMode(BLANK, OUTPUT);
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pinMode(DCPRG, OUTPUT);
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pinMode(GSCLK, OUTPUT);
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pinMode(MISO, INPUT);
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pinMode(SS,OUTPUT);
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digitalWrite(SS,HIGH); //disable device
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digitalWrite(SIN, LOW);
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digitalWrite(SCLK, LOW);
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digitalWrite(XLAT, LOW);
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digitalWrite(VPRG, LOW);
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digitalWrite(BLANK, HIGH);
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digitalWrite(GSCLK, HIGH);
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digitalWrite(DCPRG, LOW); // USE EEPROM DC register if LOW
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//////// LECTURA DE EEPROM ////////
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#if id == 0
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delay(100);
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#if first_flash
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EEPROM.write(address, 48);
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for (int i = 0; i<48; i++) EEPROM.write(address + 1 + i, command[i]); // grabamos en eeprom el caracter
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#endif
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count = EEPROM.read(address);
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if (count>63) count = 63;
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for(int i = 0; i<count; i++) command[i] = EEPROM.read(address + 1 + i);
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#endif
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//Setup the Hardware SPI registers
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// SPCR = 01010000
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//interrupt disabled,spi enabled,msb 1st,master,clk low when idle,
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//sample on leading edge of clk,system clock/4 (fastest)
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byte clr;
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SPCR = (1<<SPE)|(1<<MSTR);
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clr=SPSR;
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clr=SPDR;
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delay(10);
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Timer1.initialize(500); // set a timer of length 1000000 microseconds (or 1 sec - or 1Hz)
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Timer1.attachInterrupt( timerIsr ); // attach the service routine here
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delay(10);
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time=millis();
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}
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#if id == 0
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int limit = 16;
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#else
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int limit = 0;
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#endif
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void loop () {
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//letra(caracterA[2], espacio);
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//Serial.println(caracterA[2][1], BIN);
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//for (int i =0; i<100; i++) makemagic();
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makemagic();
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#if id == 0
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if (save)
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{
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Timer1.stop(); // set a timer of length 1000000 microseconds (or 1 sec - or 1Hz)
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//Serial.println(count);
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EEPROM.write(address, count);
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for (int i = 0; i<count; i++) EEPROM.write(address + 1 + i, command[i]); // grabamos en eeprom el caracter
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save = false;
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Timer1.initialize(500); // set a timer of length 1000000 microseconds (or 1 sec - or 1Hz)
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}
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if (((millis()-time)>=5000)||(update))
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{
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update = false;
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//for (int i = 1; i<count; i++) Serial.write(command[i]);
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bloqueo = false;
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for (int i = 1; i<limit; i++)
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{
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Serial.write(0x0F + i);
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if (((vuelta*limit) + i) >= count) Serial.write(' ');
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else Serial.write(command[(vuelta*limit) + i]);
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}
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// Serial.println();
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}
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#endif
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//letra(test1,test1);
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if (!bloqueo)
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{
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time=millis();
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if (command[limit*vuelta]==32) modo=1; //Espacio
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else if ((command[limit*vuelta]<='9')&&(command[limit*vuelta]>='0')) modo=2; //Numeros
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else if ((command[limit*vuelta]<'N')&&(command[limit*vuelta]>='A')) modo=3; //Letras de la 'A' a la 'M'
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else if ((command[limit*vuelta]<='Z')&&(command[limit*vuelta]>='N')) modo=5; //Letras de la 'N' a la 'Z' y la flecha
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else if ((command[limit*vuelta]<'n')&&(command[limit*vuelta]>='a')) modo=4; //Letras de la 'a' a 'm'
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else if ((command[limit*vuelta]<='z')&&(command[limit*vuelta]>='n')) modo=6; //Letras de la 'n' a la 'z'
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//else modo=7;
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switch (modo) {
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case 1: if (finish) {letra(espacio,espacio); modo=0;} break;
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case 2: if (finish) {letra(numero[command[limit*vuelta] - '0'],espacio); modo=0;} break;
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case 3: if (finish) {letra(caracterA[command[limit*vuelta] - 'A'],espacio); modo=0;} break;
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case 4: if (finish) {letra(caracterA[command[limit*vuelta] - 'a'],espacio); modo=0;} break;
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case 5: if (finish) {letra(caracterB[command[limit*vuelta] - 'N'],espacio); modo=0;} break;
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case 6: if (finish) {letra(caracterB[command[limit*vuelta] - 'n'],espacio); modo=0;} break;
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//case 7: if (finish) {letra(sonrisa,espacio); modo=0;} break;
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case 8: letra(espacio,espacio); if (modo==8) modo=0; finish=1; break;
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case 9: letra(test,espacio); if (modo==9) modo=0; finish=1; break;
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}
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bloqueo = true;
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int n = 0;
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if (count > 3*limit) n = 3;
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else if (count > 2*limit) n = 2;
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else if (count > limit) n = 1;
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else n = 0;
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if (vuelta < n) vuelta++;
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else vuelta = 0;
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}
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}
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void makemagic(){
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setGreysW1();
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feedPorts();
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setGreysW2();
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feedPorts();
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}
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void setGreysW1() {
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digitalWrite(BLANK, HIGH);
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digitalWrite(XLAT,LOW);
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for(int i = 21; i>=0; i--){
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spi_transfer(0x00);
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spi_transfer( (0x00) | ((levelW[2*i] & 0x0F00) >> 8) );
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spi_transfer( levelW[2*i] & 0xFF);
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}
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digitalWrite(XLAT,HIGH);
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digitalWrite(XLAT,LOW);
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digitalWrite(BLANK, LOW);
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}
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void setGreysW2() {
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digitalWrite(BLANK, HIGH);
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digitalWrite(XLAT,LOW);
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for(int i = 21; i>=0; i--){
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spi_transfer( (levelW[2*i+1] & 0x0FF0) >> 4 );
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spi_transfer( ((levelW[2*i+1] & 0xF) << 4) | (0x00) );
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spi_transfer(0x00);
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}
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digitalWrite(XLAT,HIGH);
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digitalWrite(XLAT,LOW);
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digitalWrite(BLANK, LOW);
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}
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void feedPorts() {
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// Clock for TLC5940's PWM
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digitalWrite(BLANK, HIGH);
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digitalWrite(BLANK, LOW); //=all outputs ON, start PWM cycle
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for (int i=0; i<4096; i++) {
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pulseGSCLK();
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}
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}
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void pulseGSCLK() {
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//ultra fast pulse trick, using digitalWrite caused flickering
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PORTD |= 0x80 ; // bring pin 7 high, but don't touch any of the other pins in PORTB
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//16 nanosecs is the min pulse width for the 5940, but no pause seems needed here
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PORTD &= 0x7F; // bring pin 7 low without touching the other pins in PORTB
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}
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byte letra(byte let[7], byte let_ant[7]) {
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byte letbool=0;
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byte let_new[7] = { B00000, B00000, B00000, B00000, B00000, B00000, B00000};
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for(byte j = 1; j <6; ++j){
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for(byte h = 0; h <7; ++h){
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let_new[h]=((0X1F&(let_ant[h]<<j))|(let[h]>>(5-j)));
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}
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letbool=0;
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for(byte x = 0; x < 7; ++x){ //Actualizacion de los leds
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for(byte y = 0; y <5; ++y){
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if (0x01&let_new[letbool]>>y) levelW[remap[x][y]] = 16*intensidad;
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else levelW[remap[x][y]] = 0;
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}
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//Serial.println(let_new[letbool], BIN);
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++letbool;
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}
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for(int i = 0; i <20; ++i) makemagic();
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}
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}
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byte letraWrite(byte let[7]) {
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byte letbool=0;
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letbool=0;
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for(byte x = 0; x < 7; ++x){ //Actualizacion de los leds
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for(byte y = 0; y <5; ++y){
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if (0x01&let[letbool]>>y) levelW[remap[x][y]] = 16*intensidad;
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else levelW[remap[x][y]] = 0;
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}
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++letbool;
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}
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for(int i = 0; i <20; ++i) makemagic();
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}
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