Alexandra Posta
“Race Collision” is a one player game in which a truck has to avoid “particles” that appear on the road. By the use of the joystick, the player can guide themselves through the menu system to start the game. The truck is the main element of the game and it can be moved from side to side with the joystick. The road curves randomly from time to time and the player has to be careful to keep the truck within the road boundaries. Particles appear on the screen at random positions and 4 collisions lead to the end of the game.
Dependencies: ELEC2645_JoystickLCD_LPC1768_2021
lib/N5110.cpp
- Committer:
- alex_20
- Date:
- 2021-05-06
- Revision:
- 9:6f060f495536
- Parent:
- 8:1fc5e14b0db6
File content as of revision 9:6f060f495536:
#include "mbed.h"
#include "N5110.h"
// overloaded constructor includes power pin - LCD Vcc connected to GPIO pin
// this constructor works fine with LPC1768 - enough current sourced from GPIO
// to power LCD. Doesn't work well with K64F.
N5110::N5110(PinName const pwrPin,
PinName const scePin,
PinName const rstPin,
PinName const dcPin,
PinName const mosiPin,
PinName const sclkPin,
PinName const ledPin)
:
_spi(new SPI(mosiPin,NC,sclkPin)), // create new SPI instance and initialise
_led(new DigitalOut(ledPin)),
_pwr(new DigitalOut(pwrPin)),
_sce(new DigitalOut(scePin)),
_rst(new DigitalOut(rstPin)),
_dc(new DigitalOut(dcPin))
{}
// overloaded constructor does not include power pin - LCD Vcc must be tied to +3V3
// Best to use this with K64F as the GPIO hasn't sufficient output current to reliably
// drive the LCD.
N5110::N5110(PinName const scePin,
PinName const rstPin,
PinName const dcPin,
PinName const mosiPin,
PinName const sclkPin,
PinName const ledPin)
:
_spi(new SPI(mosiPin,NC,sclkPin)), // create new SPI instance and initialise
_led(new DigitalOut(ledPin)),
_pwr(NULL), // pwr not needed so null it to be safe
_sce(new DigitalOut(scePin)),
_rst(new DigitalOut(rstPin)),
_dc(new DigitalOut(dcPin))
{}
N5110::~N5110()
{
delete _spi;
if(_pwr) {
delete _pwr;
}
delete _led;
delete _sce;
delete _rst;
delete _dc;
}
// initialise function - powers up and sends the initialisation commands
void N5110::init()
{
turnOn(); // power up
reset(); // reset LCD - must be done within 100 ms
initSPI();
backLightOn();
setContrast(0.55); // this may need tuning (say 0.4 to 0.6)
setBias(3); // datasheet - 48:1 mux - don't mess with if you don't know what you're doing! (0 to 7)
setTempCoefficient(0); // datasheet - may need increasing (range 0 to 3) at very low temperatures
normalMode(); // normal video mode by default
clearRAM(); // RAM is undefined at power-up so clear to be sure
clear(); // clear buffer
}
// sets normal video mode (black on white)
void N5110::normalMode()
{
sendCommand(0b00100000); // basic instruction
sendCommand(0b00001100); // normal video mode- datasheet
}
// sets normal video mode (white on black)
void N5110::inverseMode()
{
sendCommand(0b00100000); // basic instruction
sendCommand(0b00001101); // inverse video mode - datasheet
}
// function to power up the LCD and backlight - only works when using GPIO to power
void N5110::turnOn()
{
if (_pwr != NULL) {
_pwr->write(1); // apply power
}
}
// function to power down LCD
void N5110::turnOff()
{
clear(); // clear buffer
refresh();
backLightOff(); // turn backlight off
clearRAM(); // clear RAM to ensure specified current consumption
// send command to ensure we are in basic mode
sendCommand(0b00100000); // basic mode
sendCommand(0b00001000); // clear display
sendCommand(0b00100001); // extended mode
sendCommand(0b00100100); // power down
// if we are powering the LCD using the GPIO then make it low to turn off
if (_pwr != NULL) {
wait_ms(10); // small delay and then turn off the power pin
_pwr->write(0); // turn off power
}
}
// function to change LED backlight brightness
void N5110::backLightOn()
{
_led->write(1);
}
// function to change LED backlight brightness
void N5110::backLightOff()
{
_led->write(0);
}
void N5110::setContrast(float contrast) {
// enforce limits
if (contrast > 1.0f)
contrast = 1.0f;
else if (contrast < 0.0f)
contrast = 0.0;
// convert to char in range 0 to 127 (i.e. 6 bits)
char ic = char(contrast*127.0f);
sendCommand(0b00100001); // extended instruction set
sendCommand(0b10000000 | ic); // set Vop (which controls contrast)
sendCommand(0b00100000); // back to basic instruction set
}
void N5110::setTempCoefficient(char tc) {
// enforce limits
if (tc>3) {
tc=3;
}
// temperature coefficient may need increasing at low temperatures
sendCommand(0b00100001); // extended instruction set
sendCommand(0b00000100 | tc);
sendCommand(0b00100000); // back to basic instruction set
}
void N5110::setBias(char bias) {
// from data sheet
// bias mux rate
// 0 1:100
// 1 1:80
// 2 1:65
// 3 1:48 (default)
// 4 1:40/1:34
// 5 1:24
// 6 1:18/1:16
// 7 1:10/1:9/1:8
// enforce limits
if (bias>7) {
bias=7;
}
sendCommand(0b00100001); // extended mode instruction
sendCommand(0b00010000 | bias);
sendCommand(0b00100000); // end of extended mode instruction
}
// pulse the active low reset line
void N5110::reset()
{
_rst->write(0); // reset the LCD
_rst->write(1);
}
// function to initialise SPI peripheral
void N5110::initSPI()
{
_spi->format(8,1); // 8 bits, Mode 1 - polarity 0, phase 1 - base value of clock is 0, data captured on falling edge/propagated on rising edge
_spi->frequency(4000000); // maximum of screen is 4 MHz
}
// send a command to the display
void N5110::sendCommand(unsigned char command)
{
_dc->write(0); // set DC low for command
_sce->write(0); // set CE low to begin frame
_spi->write(command); // send command
_dc->write(1); // turn back to data by default
_sce->write(1); // set CE high to end frame (expected for transmission of single byte)
}
// send data to the display at the current XY address
// dc is set to 1 (i.e. data) after sending a command and so should
// be the default mode.
void N5110::sendData(unsigned char data)
{
_sce->write(0); // set CE low to begin frame
_spi->write(data);
_sce->write(1); // set CE high to end frame (expected for transmission of single byte)
}
// this function writes 0 to the 504 bytes to clear the RAM
void N5110::clearRAM()
{
_sce->write(0); //set CE low to begin frame
for(int i = 0; i < WIDTH * HEIGHT; i++) { // 48 x 84 bits = 504 bytes
_spi->write(0x00); // send 0's
}
_sce->write(1); // set CE high to end frame
}
// function to set the XY address in RAM for subsequenct data write
void N5110::setXYAddress(unsigned int const x,
unsigned int const y)
{
if (x<WIDTH && y<HEIGHT) { // check within range
sendCommand(0b00100000); // basic instruction
sendCommand(0b10000000 | x); // send addresses to display with relevant mask
sendCommand(0b01000000 | y);
}
}
// These functions are used to set, clear and get the value of pixels in the display
// Pixels are addressed in the range of 0 to 47 (y) and 0 to 83 (x). The refresh()
// function must be called after set and clear in order to update the display
void N5110::setPixel(unsigned int const x,
unsigned int const y,
bool const state)
{
if (x<WIDTH && y<HEIGHT) { // check within range
// calculate bank and shift 1 to required position in the data byte
if(state) buffer[x][y/8] |= (1 << y%8);
else buffer[x][y/8] &= ~(1 << y%8);
}
}
void N5110::clearPixel(unsigned int const x,
unsigned int const y)
{
if (x<WIDTH && y<HEIGHT) { // check within range
// calculate bank and shift 1 to required position (using bit clear)
buffer[x][y/8] &= ~(1 << y%8);
}
}
int N5110::getPixel(unsigned int const x,
unsigned int const y) const
{
if (x<WIDTH && y<HEIGHT) { // check within range
// return relevant bank and mask required bit
int pixel = (int) buffer[x][y/8] & (1 << y%8);
if (pixel)
return 1;
else
return 0;
}
return 0;
}
// function to refresh the display
void N5110::refresh()
{
setXYAddress(0,0); // important to set address back to 0,0 before refreshing display
// address auto increments after printing string, so buffer[0][0] will not coincide
// with top-left pixel after priting string
_sce->write(0); //set CE low to begin frame
for(int j = 0; j < BANKS; j++) { // be careful to use correct order (j,i) for horizontal addressing
for(int i = 0; i < WIDTH; i++) {
_spi->write(buffer[i][j]); // send buffer
}
}
_sce->write(1); // set CE high to end frame
}
// fills the buffer with random bytes. Can be used to test the display.
// The rand() function isn't seeded so it probably creates the same pattern everytime
void N5110::randomiseBuffer()
{
int i,j;
for(j = 0; j < BANKS; j++) { // be careful to use correct order (j,i) for horizontal addressing
for(i = 0; i < WIDTH; i++) {
buffer[i][j] = rand()%256; // generate random byte
}
}
}
// function to print 5x7 font
void N5110::printChar(char const c,
unsigned int const x,
unsigned int const y)
{
if (y<BANKS) { // check if printing in range of y banks
for (int i = 0; i < 5 ; i++ ) {
int pixel_x = x+i;
if (pixel_x > WIDTH-1) // ensure pixel isn't outside the buffer size (0 - 83)
break;
buffer[pixel_x][y] = font5x7[(c - 32)*5 + i];
// array is offset by 32 relative to ASCII, each character is 5 pixels wide
}
}
}
// function to print string at specified position
void N5110::printString(const char *str,
unsigned int const x,
unsigned int const y)
{
if (y<BANKS) { // check if printing in range of y banks
int n = 0 ; // counter for number of characters in string
// loop through string and print character
while(*str) {
// writes the character bitmap data to the buffer, so that
// text and pixels can be displayed at the same time
for (int i = 0; i < 5 ; i++ ) {
int pixel_x = x+i+n*6;
if (pixel_x > WIDTH-1) // ensure pixel isn't outside the buffer size (0 - 83)
break;
buffer[pixel_x][y] = font5x7[(*str - 32)*5 + i];
}
str++; // go to next character in string
n++; // increment index
}
}
}
// function to clear the screen buffer
void N5110::clear()
{
memset(buffer,0,sizeof(buffer));
}
// function to plot array on display
void N5110::plotArray(float const array[])
{
for (int i=0; i<WIDTH; i++) { // loop through array
// elements are normalised from 0.0 to 1.0, so multiply
// by 47 to convert to pixel range, and subtract from 47
// since top-left is 0,0 in the display geometry
setPixel(i,47 - int(array[i]*47.0f),true);
}
}
// function to draw circle
void N5110:: drawCircle(unsigned int const x0,
unsigned int const y0,
unsigned int const radius,
FillType const fill)
{
// from http://en.wikipedia.org/wiki/Midpoint_circle_algorithm
int x = radius;
int y = 0;
int radiusError = 1-x;
while(x >= y) {
// if transparent, just draw outline
if (fill == FILL_TRANSPARENT) {
setPixel( x + x0, y + y0,true);
setPixel(-x + x0, y + y0,true);
setPixel( y + x0, x + y0,true);
setPixel(-y + x0, x + y0,true);
setPixel(-y + x0, -x + y0,true);
setPixel( y + x0, -x + y0,true);
setPixel( x + x0, -y + y0,true);
setPixel(-x + x0, -y + y0,true);
} else { // drawing filled circle, so draw lines between points at same y value
int type = (fill==FILL_BLACK) ? 1:0; // black or white fill
drawLine(x+x0,y+y0,-x+x0,y+y0,0,type);
drawLine(y+x0,x+y0,-y+x0,x+y0,0,type);
drawLine(y+x0,-x+y0,-y+x0,-x+y0,0,type);
drawLine(x+x0,-y+y0,-x+x0,-y+y0,0,type);
}
y++;
if (radiusError < 0) {
radiusError += 2 * y + 1;
} else {
x--;
radiusError += 2 * (y - x) + 1;
}
}
}
// function to draw ellipse
void N5110:: drawEllipse(unsigned int const xc,
unsigned int const yc,
unsigned int const rx,
unsigned int const ry)
{
int rx2 = rx*rx, ry2 = ry*ry;
int x = 0, y = ry; //Starting point
int incSW = ry2*2 + rx2*2;
// Slopes deduced from incremental algorithm with the second-order logic
int W = ry2*(-2*x + 3);
int S = rx2*(-2*y + 3);
int SW = W + S;
// Decision parameter of Region 1 and Region 2
int p1 = ry2 - rx2*ry + rx2/4;
int p2 = ry2*(x - 0.5)*(x - 0.5) + rx2*(y - 1)*(y - 1) - rx2*ry2;
// Region 1
while(rx2*(y-0.5) >= ry2*(-x-1)) {
// Set points based on 4-way symmetry
setPixel(-x+xc,-y+yc, true);
setPixel(-x+xc, y+yc, true);
setPixel( x+xc, y+yc, true);
setPixel( x+xc,-y+yc, true);
if(p1 > 0) {
p1 += SW;
W += ry2*2;
SW += incSW;
y--;
}
else {
p1 += W;
W += 2*ry2;
SW += 2*ry2;
}
x--;
}
SW = ry2*(2 - 2*x) + rx2*(-2*y + 3);
// Region 2
while(y >= 0) {
// Set points based on 4-way symmetry
setPixel(-x+xc,-y+yc, true);
setPixel(-x+xc, y+yc, true);
setPixel( x+xc, y+yc, true);
setPixel( x+xc,-y+yc, true);
if(p2 > 0) {
p2 += S;
S += rx2*2;
SW += rx2*2;
}
else {
p2 += SW;
SW += incSW;
S += rx2*2;
x--;
}
y--;
}
}
// take points on a curve, decide whether to draw them or not
void N5110::drawCurve(std::vector<Vector2Df> curve_points, float offset, int dash_len, int type)
{
if(type == TYPE_SOLID){
for(int i = 0; i < curve_points.size()-1; i++){
// take the current and the following coordinates and draw a line between them
drawLine(static_cast<int>(curve_points[i].x),static_cast<int>(curve_points[i].y),
static_cast<int>(curve_points[i+1].x),static_cast<int>(curve_points[i+1].y),0,1);
}
}
if(type == TYPE_DOTTED){
int counter = 0;
for(int i = curve_points.size()-1; i > 0 ; i--){
int x0 = static_cast<int>(curve_points[i].x);
int x1 = static_cast<int>(curve_points[i-1].x);
int y0 = static_cast<int>(curve_points[i].y);
int y1 = static_cast<int>(curve_points[i-1].y);
int const y_range = y0 - y1;
int const x_range = x1 - x0;
// ensure we loop from smallest to largest or else for-loop won't run as expected
//unsigned int const start = y_range > 0 ? y0:y1;
//unsigned int const stop = y_range > 0 ? y1:y0;
for (unsigned int y = y0; y <= y1 ; y++) {
// do linear interpolation
int const dy = y0 - y;
unsigned int const x = x0 + (x_range * (dy / (float)y_range));
// If the line type is '0', this will clear the pixel
// If it is '1' or '2', the pixel will be set
setPixel(x,y, fmod(pow(counter, 0.6) - fmod(offset, (2 * dash_len)), (2 * dash_len)) < dash_len);
counter++;
}
}
}
}
void N5110::drawLine(unsigned int const x0,
unsigned int const y0,
unsigned int const x1,
unsigned int const y1,
unsigned int const offset,
unsigned int const step)
{
// Note that the ranges can be negative so we have to turn the input values
// into signed integers first
int const y_range = static_cast<int>(y1) - static_cast<int>(y0);
int const x_range = static_cast<int>(x1) - static_cast<int>(x0);
// make sure we loop over the largest range to get the most pixels on the display
// for instance, if drawing a vertical line (x_range = 0), we need to loop down the y pixels
// or else we'll only end up with 1 pixel in the x column
if ( abs(x_range) > abs(y_range) ) {
// ensure we loop from smallest to largest or else for-loop won't run as expected
unsigned int const start = x_range > 0 ? x0:x1;
unsigned int const stop = x_range > 0 ? x1:x0;
// loop between x pixels
for (unsigned int x = start; x<= stop ; x+=step) {
// do linear interpolation
int const dx = static_cast<int>(x) - static_cast<int>(x0);
unsigned int const y = y0 + y_range * dx / x_range;
// If the line type is '0', this will clear the pixel
// If it is '1' or '2', the pixel will be set
setPixel(x,y, FILL_BLACK);
}
} else {
// ensure we loop from smallest to largest or else for-loop won't run as expected
unsigned int const start = y_range > 0 ? y0:y1;
unsigned int const stop = y_range > 0 ? y1:y0;
for (unsigned int y = start; y<= stop ; y+=step) {
// do linear interpolation
int const dy = static_cast<int>(y)-static_cast<int>(y0);
unsigned int const x = x0 + x_range * dy / y_range;
// If the line type is '0', this will clear the pixel
// If it is '1' or '2', the pixel will be set
setPixel(x,y, FILL_BLACK);
}
}
}
void N5110::drawRect(unsigned int const x0,
unsigned int const y0,
unsigned int const width,
unsigned int const height,
FillType const fill)
{
if (fill == FILL_TRANSPARENT) { // transparent, just outline
drawLine(x0,y0,x0+(width-1),y0,0,1); // top
drawLine(x0,y0+(height-1),x0+(width-1),y0+(height-1),0,1); // bottom
drawLine(x0,y0,x0,y0+(height-1),0,1); // left
drawLine(x0+(width-1),y0,x0+(width-1),y0+(height-1),0,1); // right
} else { // filled rectangle
int step = (fill==FILL_BLACK) ? 1:0; // black or white fill
for (int y = y0; y<y0+height; y++) { // loop through rows of rectangle
drawLine(x0,y,x0+(width-1),y,0,step); // draw line across screen
}
}
}
void N5110::drawSprite(int x0,
int y0,
int nrows,
int ncols,
int *sprite)
{
for (int i = 0; i < nrows; i++) {
for (int j = 0 ; j < ncols ; j++) {
int pixel = *((sprite+i*ncols)+j);
setPixel(x0+j,y0+i, pixel);
}
}
}