#include #include int iByte; byte col = 0; byte leds[12][4]; byte pass = 1; int fadecount = 1; const int fadelimit = 3000; const int fadelimitshort = 1000; byte mode = 4; byte brightness = 2; boolean changemode = 0; int rain = 0; const int rainlimit = 5000; const int rainfade = 5000; byte rx = 0; byte ry = 0; // pin[xx] on led matrix connected to nn on Arduino (-1 is dummy to make array start at pos 1) int pins[17] = { -1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 16, 14, 15, 18, 19, 20, 21 }; // col[xx] of leds = pin yy on led matrix int cols[12] = { pins[8], pins[7], pins[6], pins[5], pins[9], pins[10], pins[11], pins[12], pins[13], pins[14], pins[15], pins[16] }; // row[xx] of leds = pin yy on led matrix int rows[4] = { pins[1], pins[2], pins[3], pins[4] }; #define DELAY 0 extern byte leds[12][4]; void setup() { Serial1.begin(9600); setupLeds(); for (int s = 0; s < 5; s++) { for ( int r = 1; r < 9; r++) { delayMicroseconds(65000); delayMicroseconds(65000); for (int j = 0; j < 4; j++) { for (int i = 0; i < 12; i++) { leds[i][j] = 1; for (int p = 0; p < 25; p++) { } leds[i][j] = r; } } } for ( int r = 9; r > 0; r--) { delayMicroseconds(65000); delayMicroseconds(65000); delayMicroseconds(65000); for (int j = 0; j < 4; j++) { for (int i = 0; i < 12; i++) { leds[i][j] = 1; for (int p = 0; p < 25; p++) { } leds[i][j] = r; } } } } } void loop() { switch (mode) { case 0: //Blacklight for (int i = 0; i < 12; i++) { for (int j = 0; j < 4; j++) { leds[i][j] = brightness; } } checkserial(); break; case 1: //Breathing for ( int r = 1; r < 9; r++) { checkserial(); if (changemode == 0) { delayMicroseconds(65000); delayMicroseconds(65000); delayMicroseconds(65000); for (int j = 0; j < 4; j++) { for (int i = 0; i < 12; i++) { leds[i][j] = 1; for (int p = 0; p < 25; p++) { } leds[i][j] = r; } } } else { break; } } for ( int r = 9; r > 0; r--) { checkserial(); if (changemode == 0) { delayMicroseconds(65000); delayMicroseconds(65000); delayMicroseconds(65000); delayMicroseconds(65000); for (int j = 0; j < 4; j++) { for (int i = 0; i < 12; i++) { leds[i][j] = 1; for (int p = 0; p < 25; p++) { } leds[i][j] = r; } } } else { break; } } for ( int r = 1; r < 30; r++) { checkserial(); if (changemode == 0) { delayMicroseconds(65000); delayMicroseconds(65000); } else { break; } } break; case 2: //Random leds[random(12)][random(4)] = random(8); delayMicroseconds(10000); checkserial(); break; case 3: //Rain rain++; if (rain > rainlimit) { rain = 0; rx = random(12); ry = random(4); if (leds[rx][ry] == 0) { leds[rx][ry] = 18; } } fadecount++; if (fadecount > rainfade) { fadecount = 1; for (int i = 0; i < 12; i++) { for (int j = 0; j < 4; j++) { if (leds[i][j] > 0) { leds[i][j] = leds[i][j] - 1; } } } } checkserial(); break; case 4: //Reactive fadecount++; if (fadecount > fadelimit) { fadecount = 1; for (int i = 0; i < 12; i++) { for (int j = 0; j < 4; j++) { if (leds[i][j] > 0) { leds[i][j] = leds[i][j] - 1; } } } } checkserial(); break; case 5: //Reactive Target fadecount++; if (fadecount > fadelimitshort) { fadecount = 1; for (int i = 0; i < 12; i++) { for (int j = 0; j < 4; j++) { if (leds[i][j] > 0) { leds[i][j] = leds[i][j] - 1; } } } } checkserial(); break; default: mode = 0; break; } changemode = 0; } void checkserial() { if (Serial1.available() > 0) { iByte = Serial1.read(); if (iByte == 100) { brightness++; if (brightness > 9) { brightness = 1; } } if (iByte == 101) { mode++; } if (iByte < 100) { if (mode == 4) { byte row = iByte / 16; byte col = iByte % 16; leds[col][row] = 18; } if (mode == 5) { byte row = iByte / 16; byte col = iByte % 16; for (byte i = 0; i < 12; i++) { leds[i][row] = 18; } for (byte p = 0; p < 4; p++) { leds[col][p] = 18; } } } } } void setupLeds() { // sets the pins as output FastGPIO::Pin<2>::setOutputLow(); FastGPIO::Pin<3>::setOutputLow(); FastGPIO::Pin<4>::setOutputLow(); FastGPIO::Pin<5>::setOutputLow(); FastGPIO::Pin<6>::setOutputLow(); FastGPIO::Pin<7>::setOutputLow(); FastGPIO::Pin<8>::setOutputLow(); FastGPIO::Pin<9>::setOutputLow(); FastGPIO::Pin<10>::setOutputLow(); FastGPIO::Pin<16>::setOutputLow(); FastGPIO::Pin<14>::setOutputLow(); FastGPIO::Pin<15>::setOutputLow(); FastGPIO::Pin<18>::setOutputLow(); FastGPIO::Pin<19>::setOutputLow(); FastGPIO::Pin<20>::setOutputLow(); FastGPIO::Pin<21>::setOutputLow(); // set up Cols FastGPIO::Pin<6>::setOutputValueLow(); FastGPIO::Pin<7>::setOutputValueLow(); FastGPIO::Pin<8>::setOutputValueLow(); FastGPIO::Pin<9>::setOutputValueLow(); FastGPIO::Pin<10>::setOutputValueLow(); FastGPIO::Pin<16>::setOutputValueLow(); FastGPIO::Pin<14>::setOutputValueLow(); FastGPIO::Pin<15>::setOutputValueLow(); FastGPIO::Pin<18>::setOutputValueLow(); FastGPIO::Pin<19>::setOutputValueLow(); FastGPIO::Pin<20>::setOutputValueLow(); FastGPIO::Pin<21>::setOutputValueLow(); // set up Rows FastGPIO::Pin<2>::setOutputValueLow(); FastGPIO::Pin<3>::setOutputValueLow(); FastGPIO::Pin<4>::setOutputValueLow(); FastGPIO::Pin<5>::setOutputValueLow(); clearLeds(); Timer1.initialize(25); Timer1.attachInterrupt(display); } void clearLeds() { // Clear display array for (int i = 0; i < 12; i++) { for (int j = 0; j < 4; j++) { leds[i][j] = 0; } } } void onLeds() { // Clear display array for (int i = 0; i < 12; i++) { for (int j = 0; j < 4; j++) { leds[i][j] = 7; } } } // Interrupt routine void display() { switch (col) { // Turn whole previous column off case 0: FastGPIO::Pin<6>::setOutputValueLow(); break; case 1: FastGPIO::Pin<7>::setOutputValueLow(); break; case 2: FastGPIO::Pin<8>::setOutputValueLow(); break; case 3: FastGPIO::Pin<9>::setOutputValueLow(); break; case 4: FastGPIO::Pin<10>::setOutputValueLow(); break; case 5: FastGPIO::Pin<16>::setOutputValueLow(); break; case 6: FastGPIO::Pin<14>::setOutputValueLow(); break; case 7: FastGPIO::Pin<15>::setOutputValueLow(); break; case 8: FastGPIO::Pin<18>::setOutputValueLow(); break; case 9: FastGPIO::Pin<19>::setOutputValueLow(); break; case 10: FastGPIO::Pin<20>::setOutputValueLow(); break; case 11: FastGPIO::Pin<21>::setOutputValueLow(); break; } col++; if (col == 12) { col = 0; pass++; if (pass > 8) { pass = 1; } } for (int row = 0; row < 4; row++) { if (leds[col][row] > pass) { switch (row) { // Turn on this led case 0: FastGPIO::Pin<2>::setOutputValueLow(); break; case 1: FastGPIO::Pin<3>::setOutputValueLow(); break; case 2: FastGPIO::Pin<4>::setOutputValueLow(); break; case 3: FastGPIO::Pin<5>::setOutputValueLow(); break; } } else { switch (row) { // Turn off this led case 0: FastGPIO::Pin<2>::setOutputValueHigh(); break; case 1: FastGPIO::Pin<3>::setOutputValueHigh(); break; case 2: FastGPIO::Pin<4>::setOutputValueHigh(); break; case 3: FastGPIO::Pin<5>::setOutputValueHigh(); break; } } } switch (col) { // Turn column on case 0: FastGPIO::Pin<6>::setOutputValueHigh(); break; case 1: FastGPIO::Pin<7>::setOutputValueHigh(); break; case 2: FastGPIO::Pin<8>::setOutputValueHigh(); break; case 3: FastGPIO::Pin<9>::setOutputValueHigh(); break; case 4: FastGPIO::Pin<10>::setOutputValueHigh(); break; case 5: FastGPIO::Pin<16>::setOutputValueHigh(); break; case 6: FastGPIO::Pin<14>::setOutputValueHigh(); break; case 7: FastGPIO::Pin<15>::setOutputValueHigh(); break; case 8: FastGPIO::Pin<18>::setOutputValueHigh(); break; case 9: FastGPIO::Pin<19>::setOutputValueHigh(); break; case 10: FastGPIO::Pin<20>::setOutputValueHigh(); break; case 11: FastGPIO::Pin<21>::setOutputValueHigh(); break; } }