Anna Dot
Programa de MIP
Dependencies: bloques ball mbed WS2812 PixelArray tsi_sensor TSI bloque MMA8451Q
main.cpp
- Committer:
- anna_dot
- Date:
- 2021-05-25
- Revision:
- 16:eab9a8d27969
- Parent:
- 15:706dd4761fbe
- Child:
- 17:0ecf3108f79e
File content as of revision 16:eab9a8d27969:
#include "mbed.h"
#include "WS2812.h"
#include "PixelArray.h"
#include "TSISensor.h"
#include "MMA8451Q.h"
#include "ball.h"
#include "bloques.h"
#define WS2812_BUF 256
#define NUM_COLORS 6
#define NUM_LEDS_PER_COLOR 10
#define NUM_LEDS_BARRA 4
#define ACCEL_ADRESS_I2C (0X1D<<1)
#define DIMENSION_TABLERO 16
PixelArray px(WS2812_BUF);
// See the program page for information on the timing numbers
// The given numbers are for the K64F
WS2812 ws(D9, WS2812_BUF, 0, 5, 5, 0);
MMA8451Q acc(PTE25, PTE24, ACCEL_ADRESS_I2C );
///////
Serial pc(USBTX, USBRX);
//////
TSISensor tsi;
int barra[NUM_LEDS_BARRA]={6,7,8,9};
float tsi_oldRead=0;
int counter_tsi=0;
int posAcelerometerTemp, posAcelerometer=0, posAcelerometerOLD=0, posAcelerometerOLD1=0, contadorReboteA=0;
int posSliderTouchTemp, posSliderTouch=0, posSliderTouchOLD=0, posSliderTouchOLD1=0, contadorRebote=0;
int matrix_tablero[DIMENSION_TABLERO][DIMENSION_TABLERO]={};
ball m_ball;
bool direct_ball=0;
Ticker refresh_ball;
bloques Bloques;
int angle=1;
bool lose=false;
void update_barra(int led_apagar, int led_encender, int act_barra );
void tsi_ctr_modeBtn(float tsi_newRead);
void tsi_ctr_modeSlider(float tsi_newRead);
void accel_ctr();
void print_pixel(uint8_t valR, uint8_t valG, uint8_t valB, int numPixelMatrix_i, int numPixelMatrix_j, int numPixelMatrixOLD_i, int numPixelMatrixOLD_j, uint8_t size=1);
void setPixelColor(int numPixelMatrix, int r, int g, int b);
void ctr_ball();
void clear_matrix();
void angle_rebote();
int main()
{
int sel_opcio=0;
pc.baud(115200);
pc.printf("\r\n\r\nHola!\r\ncompilado el " __DATE__ ", " __TIME__ "\r\n");
ws.useII(WS2812::PER_PIXEL); // use per-pixel intensity scaling
for(int i=0; i<Bloques.getNumBloques(); i++){
bloque temp_blq=Bloques.getBloque(i);
print_pixel(temp_blq.getColR(),temp_blq.getColG(),temp_blq.getColB(), temp_blq.getCoordX(),temp_blq.getCoordY(), -1, -1, temp_blq.getSize());
}
// set up the colours we want to draw with
//int colorbuf[NUM_COLORS] = {0x2f0000,0x2f2f00,0x002f00,0x002f2f,0x00002f,0x2f002f};
// for each of the colours (j) write out 10 of them
// the pixels are written at the colour*10, plus the colour position
// all modulus 60 so it wraps around
/*for (int i = 0; i < WS2812_BUF; i++) {
px.Set(i, colorbuf[(i / NUM_LEDS_PER_COLOR) % NUM_COLORS]);
}*/
for(int i=0; i<NUM_LEDS_BARRA; i++){
px.Set(barra[i], 0x2f0000);
}
for(int i=0; i<NUM_LEDS_BARRA; i++){
px.SetI(barra[i]%WS2812_BUF, 255); //0xff
}
/*for(int i=0; i<NUM_LEDS_BARRA; i++){
matrix_tablero[0][barra[i]]=1;
}*/
print_pixel(255, 255, 255, m_ball.getCoordX(), m_ball.getCoordY(),-1,-1);
//print_pixel(255, 255, 255, 0, 0,-1,-1);
// Now the buffer is written, rotate it
// by writing it out with an increasing offset
ws.write(px.getBuf());
refresh_ball.attach(&ctr_ball, 0.4);
while (1) {
/*for (int z=WS2812_BUF; z >= 0 ; z--) {
ws.write_offsets(px.getBuf(),z,z,z);
wait(0.075);
}*/
if(sel_opcio==0){
tsi_ctr_modeBtn(tsi.readPercentage());
}
else{
if(sel_opcio==1){
tsi_ctr_modeSlider(tsi.readPercentage());
}
else if(sel_opcio==2){
accel_ctr();
}
}
//pc.printf("\r\n Touch %d", (rand()%(9-6 + 1) + 6));
}
}
void tsi_ctr_modeBtn(float tsi_newRead){
if(tsi_newRead!=0.0){
if(tsi_newRead>0.6 and tsi_oldRead>0.6){
counter_tsi++;
}
else {
if(tsi_newRead<0.4 and tsi_oldRead<0.4){
counter_tsi++;
}
else{
counter_tsi=0;
}
}
tsi_oldRead=tsi_newRead;
if(counter_tsi == 10450){
if( (tsi_newRead < 0.4) && tsi_newRead!=0 ){ //if left
if(barra[0]>0){
update_barra((NUM_LEDS_BARRA-1),0, -1 );
}
}
else{
if(tsi_newRead > 0.6){ //if right
if(barra[NUM_LEDS_BARRA-1]<15){
update_barra(0,(NUM_LEDS_BARRA-1), 1 );
}
}
}
//control_tsi(tsi_newRead);
ws.write(px.getBuf());
counter_tsi=0;
}
}
else{
counter_tsi=0;
}
//tsi_oldRead=tsi_newRead;
}
void tsi_ctr_modeSlider(float tsi_newRead){
//Multiplicamos lo que lee el tsi.readPercentage() por 100 para tener un porcentaje del 0 al 100% en lugar del 0 al 1 que devuelve dicha función tsi.readPercentage().
//Lo multiplicamos por 1.4 para obtener un ranto de entre 0 y 140.
//Le restamos 70 para que el 50% leido por el tsi represente el 0, de esta forma ahora el rango es de -70 a +70.
//Dividimos entre 10 para obtener unos valores entre -7 y +7 que son las posiciones que puede tomar la barra inferior si se trata de una barra de 4 pixeles como es el caso.
posSliderTouchTemp=(((tsi_newRead*100)*1.4)-70)/10;
//Controlamos que no se salga de las posiciones posibles de la barra inferior.
if(posSliderTouchTemp>-7 and posSliderTouchTemp<7){
//pc.printf("\r\n Porcentaje=%d",posSliderTouchTemp);
//Se controla los rebotes del TSI ya que sino da saltos, por eso se incrementa un contador cuando detecta una misma posicion mas de una vez seguida.
if(posSliderTouchTemp==posSliderTouchOLD1){
contadorRebote=contadorRebote+1;
}else{
contadorRebote=0;
}
posSliderTouchOLD1=posSliderTouchTemp;
if(contadorRebote>=140){
posSliderTouch=posSliderTouchTemp;
}
}
if(posSliderTouch!=posSliderTouchOLD){
//Se suaviza el movimiento de la barra inferior para que de un efecto de scroll mas bonito y no tan brusco,
//por eso se realiza un for para que pase por todas las posiciones hasta la posicoon de la barra objetivo.
if(posSliderTouch>posSliderTouchOLD){
for(int p=posSliderTouchOLD; p<posSliderTouch; p++){
update_barra(0,(NUM_LEDS_BARRA-1), 1 ); //if rigth
ws.write(px.getBuf());
//printBar( 249, 0, 0, p);
}
}else if(posSliderTouch<posSliderTouchOLD){
for(int p=posSliderTouchOLD; p>posSliderTouch; p--){
update_barra((NUM_LEDS_BARRA-1), 0, -1 ); //if left
ws.write(px.getBuf());
//printBar( 249, 0, 0, p);
}
}
posSliderTouchOLD=posSliderTouch;
//pc.printf("\r\n Touch");
}
}
void update_barra(int led_apagar, int led_encender, int act_barra ){
if(m_ball.getCoordX()!=0){
px.Set(barra[led_apagar], 0x0); //apagamos el led
for(int i=0; i<NUM_LEDS_BARRA; i++){ //actualizamos valor del array
barra[i]=barra[i]+act_barra;
//pc.printf("\r\n UPDATEEE ------- =%d", barra[i]);
}
px.Set(barra[led_encender], 0x2f0000); //encendemos el siguiente led
px.SetI(barra[led_encender]%WS2812_BUF, 255); //0xff
//ctr_ball_barra();
}
}
void accel_ctr(){
float nearest = floor(abs(((acc.getAccY()+1)*100)/2)); //para obtener un valor 0 y 100
posAcelerometerTemp=(((nearest)*2.8)-140)/10;
//pc.printf("\r\n Porcentaje=%d",posAcelerometerTemp);
if(posAcelerometerTemp<=-7){
posAcelerometerTemp=-6;
}else if(posAcelerometerTemp>=7){
posAcelerometerTemp=6;
}
if(posAcelerometerTemp>-7 and posAcelerometerTemp<7){
//pc.printf("\r\n Porcentaje=%d",posAcelerometerTemp);
//pc.printf("\r\n Ha entrat");
if(posAcelerometerTemp==posAcelerometerOLD1){
contadorReboteA=contadorReboteA+1;
}else{
contadorReboteA=0;
}
posAcelerometerOLD1=posAcelerometerTemp;
if(contadorReboteA>=40){
posAcelerometer=posAcelerometerTemp;
}
}
if(posAcelerometer!=posAcelerometerOLD){
if(posAcelerometer>posAcelerometerOLD){
for(int p=posAcelerometerOLD; p<posAcelerometer; p++){ //movemos la barrita hasta la posición actual, mostrando la animación
update_barra(0,(NUM_LEDS_BARRA-1), 1 ); //if rigth
ws.write(px.getBuf());
//pc.printf("\r\n HOLAAAA DRETA=%d",p);
}
}else if(posAcelerometer<posAcelerometerOLD){
//pc.printf("\r\n HOLAAAA ESQUERRA");
for(int p=posAcelerometerOLD; p>posAcelerometer; p--){
update_barra((NUM_LEDS_BARRA-1), 0, -1 ); //if left
ws.write(px.getBuf());
//pc.printf("\r\n HOLAAAA ESQUERRA=%d",p);
}
}
posAcelerometerOLD=posAcelerometer;
//pc.printf("\r\n Acelerometer");
}
}
void print_pixel(uint8_t valR, uint8_t valG, uint8_t valB, int numPixelMatrix_i, int numPixelMatrix_j, int numPixelMatrixOLD_i, int numPixelMatrixOLD_j, uint8_t size) {
//printf ("\r\nRGB=> %ld, %ld, %ld \r\n", valR, valG, valB);
if(numPixelMatrixOLD_i!=-1 and numPixelMatrixOLD_j!=-1){
for(int j=numPixelMatrixOLD_j; j<(numPixelMatrixOLD_j+size); j++){
uint8_t numPixelMatrixOLD;
if(numPixelMatrixOLD_i%2==0){
numPixelMatrixOLD=(numPixelMatrixOLD_i*16)+j;
}else{
numPixelMatrixOLD=((numPixelMatrixOLD_i*16)+15)-j;
}
setPixelColor(numPixelMatrixOLD, 0, 0, 0);
}
}
if(numPixelMatrix_i!=-1 or numPixelMatrix_j!=-1){
for(int j=numPixelMatrix_j; j<(numPixelMatrix_j+size); j++){
uint8_t numPixelMatrix;
if(numPixelMatrix_i%2==0){
numPixelMatrix=(numPixelMatrix_i*16)+j;
}else{
numPixelMatrix=((numPixelMatrix_i*16)+15)-j;
}
setPixelColor(numPixelMatrix, valR, valG, valB);
}
}
ws.write(px.getBuf());
}
void setPixelColor(int numPixelMatrix, int r, int g, int b){
px.SetI(numPixelMatrix,255);
px.SetR(numPixelMatrix,r);
px.SetG(numPixelMatrix,g);
px.SetB(numPixelMatrix,b);
}
void ctr_ball(){
int old_i=m_ball.getCoordX();
int old_j=m_ball.getCoordY();
bool found_barra=false;
int i=0;
if(old_i==15){
//pc.printf("TECHO Angle ANTES REBOTE --> %d \r\n", angle);
direct_ball=!direct_ball;
angle_rebote();
//pc.printf("TECHO Angle DESPUES REBOTE --> %d \r\n", angle);
}
else{
if( (old_j==15 or old_j==0) and (angle!=1)){ //and old_i!=1){
//pc.printf("PAREEEED Angle ANTES REBOTE --> %d \r\n", angle);
angle_rebote();
//pc.printf("PAREEEED Angle DESPUES REBOTE --> %d \r\n", angle);
}//else{
int predict_Y=m_ball.predict_Y_axis_barra(direct_ball, angle);
pc.printf("\r\n Coord X %d, Coord Y %d y predictY %d, angle %d, direction %d --> ",m_ball.getCoordX(), m_ball.getCoordY() , predict_Y, angle, direct_ball );
while(!found_barra and i<NUM_LEDS_BARRA){
if(barra[i]==predict_Y and old_i==1){
found_barra=true;
direct_ball=!direct_ball;
}
i++;
}
if(found_barra){
if(barra[0]==predict_Y){
angle=0;
}else{
if(barra[3]==predict_Y){
angle=2;
}else{
angle=1;
}
}
}else if(old_i==0){
refresh_ball.detach();
clear_matrix();
lose=true;
}
//}
}
/*if((barra[0]==old_j or barra[1]==old_j or barra[2]==old_j or barra[3]==old_j) and old_i==1){
direct_ball=!direct_ball;
}*/
if(!lose){
bool found_blq_i=false;
int i=0;
while(!found_blq_i and i<Bloques.getNumBloques() ){
bloque temp_blq=Bloques.getBloque(i);
if((temp_blq.getCoordX()==(m_ball.getCoordX()+1))){
found_blq_i=true;
}
i++;
}
bool found_blq_j=false;
int j=0;
if(found_blq_i){
int predict_Y=m_ball.predict_Y_axis(direct_ball, angle);
//pc.printf("\r\n Coord X %d, Coord Y %d y predictY %d, angle %d, direction %d --> ",m_ball.getCoordX(), m_ball.getCoordY() , predict_Y, angle, direct_ball );
while(!found_blq_j and j<Bloques.getNumBloques() ){
bloque temp_blq=Bloques.getBloque(j);
int blq_pos_Y=(temp_blq.getCoordY()+temp_blq.getSize());
if((blq_pos_Y>predict_Y and predict_Y>=temp_blq.getCoordY()) and temp_blq.getEnabled()){
found_blq_j=true;
direct_ball=!direct_ball;
angle_rebote();
print_pixel(temp_blq.getColR(), temp_blq.getColG(), temp_blq.getColB(), -1, -1, temp_blq.getCoordX(), temp_blq.getCoordY(), temp_blq.getSize());
Bloques.disable_blq(j);
//pc.printf("BloqY %d, temp_bloq.CoordY %d y predictY %d --> %d", blq_pos_Y, temp_blq.getCoordY() , predict_Y );
}
j++;
}
}
m_ball.movement(direct_ball, angle);
print_pixel(255, 255, 255, m_ball.getCoordX(), m_ball.getCoordY(),old_i, old_j);
}
}
void clear_matrix(){
for(int i=0; i<256; i++){
setPixelColor(i,0,0,0);
}
ws.write(px.getBuf());
}
void angle_rebote(){
if(angle==0){
angle=2;
}else if(angle==2){
angle=0;
}
}
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Repository details
| Type: | Program |
|---|---|
| Mbed OS support: | Mbed 2 deprecated |
| Created: | 19 May 2021 |
| Imports: | 1 |
| Forks: | 0 |
| Commits: | 24 |
| Dependents: | 0 |
| Dependencies: | 9 |
| Followers: | 2 |
