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openledrace/open-led-race/open-led-race.ino
Singular Devices 6925bc947a Replace open-led-race.ino
2021-07-13 07:22:21 +00:00

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/*
* ____ _ ______ _____ _____
/ __ \ | | | ____| __ \ | __ \
| | | |_ __ ___ _ __ | | | |__ | | | | | |__) |__ _ ___ ___
| | | | '_ \ / _ \ '_ \ | | | __| | | | | | _ // _` |/ __/ _ \
| |__| | |_) | __/ | | | | |____| |____| |__| | | | \ \ (_| | (_| __/
\____/| .__/ \___|_| |_| |______|______|_____/ |_| \_\__,_|\___\___|
| |
|_|
Open LED Race
An minimalist cars race for LED strip
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
First public version by:
Angel Maldonado (https://gitlab.com/angeljmc)
Gerardo Barbarov (gbarbarov AT singulardevices DOT com)
Basen on original idea and 2 players code by:
Gerardo Barbarov for Arduino day Seville 2019
https://github.com/gbarbarov/led-race
Public Repository for this code:
https://gitlab.com/open-led-race/olr-arduino
*/
// 2020/12/10 - Ver 0.9.6
// --see changelog.txt
char const softwareId[] = "A4P0"; // A4P -> A = Open LED Race, 4P0 = Game ID (4P = 4 Players, 0=Type 0)
char const version[] = "0.9.7";
#include <Adafruit_NeoPixel.h>
#include <EEPROM.h>
#include "olr-lib.h"
#include "olr-param.h"
#include "SoftTimer.h"
#include "SerialCommand.h"
#define PIN_LED 2 // R 500 ohms to DI pin for WS2812 and WS2813, for WS2813 BI pin of first LED to GND , CAP 1000 uF to VCC 5v/GND,power supplie 5V 2A
#define PIN_AUDIO 3 // through CAP 2uf to speaker 8 ohms
#define REC_COMMAND_BUFLEN 32
#define EOL '\n' // End of Command char used in Protocol
#define COLOR1 track.Color(255,0,0)
#define COLOR2 track.Color(0,255,0)
#define COLOR3 track.Color(0,0,255)
#define COLOR4 track.Color(255,255,255)
#define COLOR_RAMP track.Color(64,0,64)
#define COLOR_COIN track.Color(0,255,255)
#define COLOR_BOXMARKS track.Color(64,64,0)
#define LED_SEMAPHORE 12
#define CONTDOWN_PHASE_DURATION 2000
#define CONTDOWN_STARTSOUND_DURATION 40
#define NEWRACE_DELAY 5000
enum{
MAX_CARS = 4,
};
enum loglevel { // used in Serial Protocol "!" command (send log/error messageS)
ECHO = 0,
DISABLE = 0,
LOG = 1,
WARNING = 2,
ERROR = 3
};
enum resp{
NOK = -1,
NOTHING = 0,
OK = 1
};
typedef struct ack{
enum resp rp;
char type;
}ack_t;
struct cfgcircuit{
int outtunnel;
};
enum phases{
IDLE = 0,
CONFIG,
CONFIG_OK,
READY,
COUNTDOWN,
RACING,
PAUSE,
RESUME,
COMPLETE,
RACE_PHASES
};
struct race{
struct cfgrace cfg;
struct cfgcircuit circ;
bool newcfg;
enum phases phase;
byte numcars;
int winner;
};
byte SMOTOR=0;
int TBEEP=0;
int FBEEP=0;
/*------------------------------------------------------*/
enum loglevel verbose = DISABLE;
static struct race race;
static car_t cars[ MAX_CARS ];
static controller_t switchs[ MAX_CARS ];
static track_t tck;
static int const eeadrInfo = 0;
char txbuff[64];
static unsigned long lastmillis = 0;
SoftTimer customDelay = SoftTimer(); // non blocking delay()
// Used to manage countdown phases
int countdown_phase=1;
bool countdown_new_phase=true;
int win_music[] = {
2637, 2637, 0, 2637,
0, 2093, 2637, 0,
3136
};
//int TBEEP=3;
char tracksID[ NUM_TRACKS ][2] ={"U","M","B","I","O"};
/* ----------- Function prototypes ------------------- */
void sendResponse( ack_t *ack);
ack_t manageSerialCommand();
void printdebug( const char * msg, int errlevel );
void print_cars_positions( car_t* cars);
void run_racecycle( void );
void draw_winner( track_t* tck, uint32_t color);
char cmd[REC_COMMAND_BUFLEN]; // Stores command received by ReadSerialComand()
SerialCommand serialCommand = SerialCommand(cmd, REC_COMMAND_BUFLEN, EOL, &Serial); // get complete command from serial
Adafruit_NeoPixel track;
/*
*
*/
void setup() {
Serial.begin(115200);
randomSeed( analogRead(A6) + analogRead(A7) );
controller_setup( );
param_load( &tck.cfg );
track = Adafruit_NeoPixel( tck.cfg.track.nled_total, PIN_LED, NEO_GRB + NEO_KHZ800 );
controller_init( &switchs[0], DIGITAL_MODE, DIG_CONTROL_1 );
car_init( &cars[0], &switchs[0], COLOR1 );
controller_init( &switchs[1], DIGITAL_MODE, DIG_CONTROL_2 );
car_init( &cars[1], &switchs[1], COLOR2 );
race.numcars = 2;
if( controller_isActive( DIG_CONTROL_3 )) {
controller_init( &switchs[2], DIGITAL_MODE, DIG_CONTROL_3 );
car_init( &cars[2], &switchs[2], COLOR3 );
++race.numcars;
}
if( controller_isActive( DIG_CONTROL_4 )) {
controller_init( &switchs[3], DIGITAL_MODE, DIG_CONTROL_4 );
car_init( &cars[3], &switchs[3], COLOR4 );
++race.numcars;
}
track.begin();
strip_clear( &tck );
// Check Box before Physic/Sound to allow user to have Box and Physics with no sound
if(digitalRead(DIG_CONTROL_2)==0 || tck.cfg.track.box_alwaysOn ) { //push switch 2 on reset for activate boxes (pit lane)
box_init( &tck );
track_configure( &tck, tck.cfg.track.nled_total - tck.cfg.track.box_len );
draw_box_entrypoint( &tck );
} else{
track_configure( &tck, 0 );
}
if( digitalRead(DIG_CONTROL_1)==0 || tck.cfg.ramp.alwaysOn ) { //push switch 1 on reset for activate physics
ramp_init( &tck );
draw_ramp( &tck );
track.show();
delay(2000);
if ( digitalRead( DIG_CONTROL_1 ) == 0 ) { //retain push switch on reset for activate FX sound
SMOTOR=1;
tone(PIN_AUDIO,100);}
}
race.cfg.startline = tck.cfg.race.startline;// true;
race.cfg.nlap = tck.cfg.race.nlap;// NUMLAP;
race.cfg.nrepeat = tck.cfg.race.nrepeat;// 1;
race.cfg.finishline = tck.cfg.race.finishline;// true;
customDelay.start(0); // first race starts with no delay
race.phase = READY;
}
/*
*
*/
void loop() {
// look for commands received on serial
ack_t ack = manageSerialCommand();
if(ack.rp != NOTHING){
sendResponse(&ack);
}
// PLEASE NOTE:
// DO NOT call "track.show()" in the loop() while in configuration mode !!!
// It would mess up with Serial communication (receives only 2 bytes - if the
// string sent by the host is longer, it gets lost)
// In other phases (READY, RACING, etc) ONLY 2 bytes are guaranteed to be
// succesfully received - So "Enter Configuration Mode" command is just one byte (@)
switch(race.phase) {
case CONFIG:
{
if( race.newcfg ) {
race.newcfg = false;
countdownReset();
customDelay.start(0);
race.phase = READY;
send_phase( race.phase );
}
}
break;
case READY:
{
if(customDelay.elapsed()) {
for( int i = 0; i < race.numcars; ++i) {
car_resetPosition( &cars[i] );
cars[i].repeats = 0;
}
tck.ledcoin = COIN_RESET;
race.phase = COUNTDOWN;
send_phase( race.phase );
}
}
break;
case COUNTDOWN:
{
if( race.cfg.startline ){
// Countdown: semaphore and tones
if(start_race_done()) {
// Countdown done
for( int i = 0; i < race.numcars; ++i ) {
cars[i].st = CAR_ENTER;
}
race.phase = RACING;
send_phase( race.phase );
}
}
}
break;
case RACING:
{
strip_clear( &tck );
if( box_isactive( &tck ) ) {
if( tck.ledcoin == COIN_RESET ) {
tck.ledcoin = COIN_WAIT;
tck.ledtime = millis() + random(2000,7000);
}
if( tck.ledcoin > 0 )
draw_coin( &tck );
else if( millis() > tck.ledtime )
tck.ledcoin = random( 20, tck.cfg.track.nled_aux - 20 );
}
if( ramp_isactive( &tck ) )
draw_ramp( &tck );
if( box_isactive( &tck ) )
draw_box_entrypoint( &tck );
for( int i = 0; i < race.numcars; ++i ) {
run_racecycle( &cars[i], i );
if( cars[i].st == CAR_FINISH ) {
race.phase = COMPLETE;
race.winner = i;
send_phase( race.phase );
break;
}
}
track.show();
if (SMOTOR==1) tone(PIN_AUDIO,FBEEP+int(cars[0].speed*440*1)+int(cars[1].speed*440*2)+int(cars[2].speed*440*3)+int(cars[3].speed*440*4));
if (TBEEP>0) {TBEEP--;} else {FBEEP=0;};
// Print p command!!!
unsigned long nowmillis = millis();
if( abs( nowmillis - lastmillis ) > 100 ){
lastmillis = nowmillis;
print_cars_positions( cars );
}
// ----------------
}
break;
case COMPLETE :
{
strip_clear( &tck );
track.show();
if ( race.cfg.finishline ){
draw_winner( &tck, cars[race.winner].color );
sound_winner( &tck, race.winner );
strip_clear( &tck );
}
track.show();
customDelay.start(NEWRACE_DELAY);
race.phase = READY;
}
break;
default:
{
sprintf( txbuff, "Software Error in main loop switch()");
printdebug( txbuff, WARNING );
break;
}
} // switch
}
void send_phase( int phase ) {
sprintf(txbuff, "R%d%c",phase,EOL);
serialCommand.sendCommand(txbuff);
}
void run_racecycle( car_t *car, int i ) {
struct cfgtrack const* cfg = &tck.cfg.track;
if( car->st == CAR_ENTER ) {
car_resetPosition( car );
if( car->repeats < race.cfg.nrepeat )
car->st = CAR_RACING;
else
car->st = CAR_GO_OUT;
}
if( car->st == CAR_RACING ) {
update_track( &tck, car );
car_updateController( car );
draw_car( &tck, car );
if( car->nlap == race.cfg.nlap
&& !car->leaving
&& car->dist > ( cfg->nled_main*car->nlap - race.circ.outtunnel ) ) {
car->leaving = true;
car->st = CAR_LEAVING;
}
if( car->nlap > race.cfg.nlap ) {
++car->repeats;
car->st = CAR_GO_OUT;
}
if( car->repeats >= race.cfg.nrepeat
&& race.cfg.finishline ) {
car->st = CAR_FINISH;
}
}
if ( car->st == CAR_FINISH ){
car->trackID = NOT_TRACK;
sprintf( txbuff, "w%d%c", i + 1, EOL );
serialCommand.sendCommand(txbuff);
//sendCommand(txbuff);
car_resetPosition( car );
}
}
int get_relative_position( car_t* car ) {
enum{
MIN_RPOS = 0,
MAX_RPOS = 99,
};
struct cfgtrack const* cfg = &tck.cfg.track;
int trackdist = 0;
int pos = 0;
switch ( car->trackID ){
case TRACK_MAIN:
trackdist = (int)car->dist % cfg->nled_main;
pos = map(trackdist, 0, cfg->nled_main -1, MIN_RPOS, MAX_RPOS);
break;
case TRACK_AUX:
trackdist = (int)car->dist_aux;
pos = map(trackdist, 0, cfg->nled_aux -1, MIN_RPOS, MAX_RPOS);
break;
}
return pos;
}
void print_cars_positions( car_t* cars ) {
bool outallcar = true;
for( int i = 0; i < race.numcars; ++i)
outallcar &= cars[i].st == CAR_WAITING;
if ( outallcar ) return;
for( int i = 0; i < race.numcars; ++i ) {
int const rpos = get_relative_position( &cars[i] );
sprintf( txbuff, "p%d%s%d,%d,%d%c", i + 1, tracksID[cars[i].trackID], cars[i].nlap, rpos,(int)cars[i].battery, EOL );
serialCommand.sendCommand(txbuff);
//sendCommand(txbuff);
}
}
/*
* non-blocking version
*/
boolean start_race_done( ) {
if(countdown_new_phase){
countdown_new_phase=false;
//customDelay.start(CONTDOWN_PHASE_DURATION);
customDelay.start(CONTDOWN_PHASE_DURATION);
strip_clear( &tck );
if(ramp_isactive( &tck )) draw_ramp( &tck );
if(box_isactive( &tck )) draw_box_entrypoint( &tck );
switch(countdown_phase) {
case 1:
tone(PIN_AUDIO,400);
track.setPixelColor(LED_SEMAPHORE, track.Color(255,0,0));
break;
case 2:
tone(PIN_AUDIO,600);
track.setPixelColor(LED_SEMAPHORE, track.Color(0,0,0));
track.setPixelColor(LED_SEMAPHORE-1, track.Color(255,255,0));
break;
case 3:
tone(PIN_AUDIO,1200);
track.setPixelColor(LED_SEMAPHORE-1, track.Color(0,0,0));
track.setPixelColor(LED_SEMAPHORE-2, track.Color(0,255,0));
break;
case 4:
//customDelay.start(CONTDOWN_STARTSOUND_DURATION);
customDelay.start(CONTDOWN_STARTSOUND_DURATION);
tone(PIN_AUDIO,880);
track.setPixelColor(LED_SEMAPHORE-2, track.Color(0,0,0));
track.setPixelColor(0, track.Color(255,255,255));
break;
case 5:
noTone(PIN_AUDIO);
countdownReset(); // reset for next countdown
return(true);
}
track.show();
}
if(customDelay.elapsed()) {
noTone(PIN_AUDIO);
countdown_new_phase=true;
countdown_phase++;
}
return(false);
}
/*
*
*/
void countdownReset() {
countdown_phase=1;
countdown_new_phase=true;
}
void sound_winner( track_t* tck, int winner ) {
int const msize = sizeof(win_music) / sizeof(int);
for (int note = 0; note < msize; note++) {
tone(PIN_AUDIO, win_music[note],200);
delay(230);
noTone(PIN_AUDIO);
}
}
void strip_clear( track_t* tck ) {
struct cfgtrack const* cfg = &tck->cfg.track;
for( int i=0; i < cfg->nled_main; i++)
track.setPixelColor( i, track.Color(0,0,0) );
for( int i=0; i < cfg->nled_aux; i++)
track.setPixelColor( cfg->nled_main+i, track.Color(0,0,0) );
}
void draw_coin( track_t* tck ) {
struct cfgtrack const* cfg = &tck->cfg.track;
track.setPixelColor( 1 + cfg->nled_main + cfg->nled_aux - tck->ledcoin,COLOR_COIN );
}
void draw_winner( track_t* tck, uint32_t color) {
struct cfgtrack const* cfg = &tck->cfg.track;
for(int i=16; i < cfg->nled_main; i=i+(8 * cfg->nled_main / 300 )){
track.setPixelColor( i , color );
track.setPixelColor( i-16 ,0 );
track.show();
}
}
void draw_car_tail( track_t* tck, car_t* car ) {
struct cfgtrack const* cfg = &tck->cfg.track;
switch ( car->trackID ){
case TRACK_MAIN:
for(int i=0; i<= car->nlap; ++i )
track.setPixelColor( ((word)car->dist % cfg->nled_main) + i, car->color );
break;
case TRACK_AUX:
for(int i=0; i<= car->nlap; ++i )
track.setPixelColor( (word)(cfg->nled_main + cfg->nled_aux - car->dist_aux) + i, car->color);
break;
}
}
void draw_car( track_t* tck, car_t* car ) {
struct cfgtrack const* cfg = &tck->cfg.track;
switch ( car->trackID ){
case TRACK_MAIN:
for(int i=0; i<=1; ++i )
track.setPixelColor( ((word)car->dist % cfg->nled_main) - i, car->color );
if ( (car->battery<=BATTERY_MIN) && ((millis()%100)>50)) track.setPixelColor( ((word)car->dist % cfg->nled_main) - 2, 0x493905 );
break;
case TRACK_AUX:
for(int i=0; i<=1; ++i )
track.setPixelColor( (word)(cfg->nled_main + cfg->nled_aux - car->dist_aux) + i, car->color);
if ( (car->battery<=BATTERY_MIN) && ((millis()%100)>50) ) track.setPixelColor( (word)(cfg->nled_main + cfg->nled_aux - car->dist_aux) + 2, 0x493905);
break;
}
}
/*
* Display on LED Strip current values for Slope and Pitlane
*
*/
void show_cfgpars_onstrip(){
strip_clear( &tck );
if( ramp_isactive( &tck ) )
draw_ramp( &tck );
if( box_isactive( &tck ) )
draw_box_entrypoint( &tck );
track.show();
}
/*
*
*/
void draw_ramp( track_t* _tck ) {
struct cfgramp const* r = &_tck->cfg.ramp;
byte dist = 0;
byte intensity = 0;
for( int i = r->init; i <= r->center; ++i ) {
dist = r->center - r->init;
intensity = ( 32 * (i - r->init) ) / dist;
track.setPixelColor( i, track.Color( intensity,0,intensity ) );
}
for( int i = r->center; i <= r->end; ++i ) {
dist = r->end - r->center;
intensity = ( 32 * ( r->end - i ) ) / dist;
track.setPixelColor( i, track.Color( intensity,0,intensity ) );
}
}
/*
*
*/
void draw_box_entrypoint( track_t* _tck ) {
struct cfgtrack const* cfg = &_tck->cfg.track;
int out = cfg->nled_total - cfg->box_len; // Pit lane exit (race start)
int in = out - cfg->box_len; // Pit lane Entrance
track.setPixelColor(in ,COLOR_BOXMARKS );
track.setPixelColor(out ,COLOR_BOXMARKS );
}
/*
* Check Serial to see if there is a command ready to be processed
*
*/
ack_t manageSerialCommand() {
ack_t ack = { .rp = NOTHING, .type = '\0' };
int clen = serialCommand.checkSerial();
if(clen == 0) return ack; // No commands received
if(clen < 0) { // Error receiving command
sprintf( txbuff, "Error reading serial command:[%d]",clen);
printdebug( txbuff, WARNING );
}
// clen > 0 ---> Command with length=clen ready in cmd[]
ack.rp=NOK;
switch (cmd[0]) {
case '#': // Handshake
{
ack.type = cmd[0];
sprintf( txbuff, "#%c", EOL );
serialCommand.sendCommand(txbuff);
ack.rp = NOTHING;
}
break;
case '@' : // Enter "Configuration Mode" status
{
ack.type = cmd[0];
if(race.phase != CONFIG) {// Ignore command if Board already in "Configure Mode"
race.phase = CONFIG;
enter_configuration_mode();
}
ack.rp = OK;
}
break;
case '~' : // Exit "Configure Mode"
{
ack.type = cmd[0];
if(race.phase == CONFIG) { // Ignore command if Board is not in "Configure Mode"
race.newcfg = true;
}
ack.rp = OK;
}
break;
case 'R' : // Set Race Phase
{
ack.type = cmd[0];
int const phase = atoi( cmd + 1);
if( 0 > phase || RACE_PHASES <= phase) return ack;
race.phase = (enum phases) phase;
ack.rp = OK;
if ( race.phase == CONFIG ) { // accept R1 as a EnterConfigurationMode command - DEPRECATED
enter_configuration_mode();
}
}
break;
case 'C' : //Parse race configuration -> C1,2,3,0
{
ack.type = cmd[0];
char * pch = strtok (cmd,"C");
if( !pch ) return ack;
pch = strtok (pch, "," );
if( !pch ) return ack;
int startline = atoi( pch );
pch = strtok (NULL, ",");
if( !pch ) return ack;
int nlap = atoi( pch );
pch = strtok (NULL, ",");
if( !pch ) return ack;
int nrepeat = atoi( pch );
pch = strtok (NULL, ",");
if( !pch ) return ack;
int finishline = atoi( pch );
int err = race_configure( &tck, startline, nlap, nrepeat, finishline);
if( err ) return ack;
race.cfg.startline = tck.cfg.race.startline;
race.cfg.nlap = tck.cfg.race.nlap;
race.cfg.nrepeat = tck.cfg.race.nrepeat;
race.cfg.finishline = tck.cfg.race.finishline;
ack.rp = OK;
}
break;
case 'T' : //Parse Track configuration -> Track length
{
ack.type = cmd[0];
char * pch = strtok (cmd,"T");
if( !pch ) return ack;
int nled = atoi( cmd + 1 );
int err = tracklen_configure( &tck, nled);
if( err ) return ack;
track_configure( &tck, 0);
if( err ) return ack;
ack.rp = OK;
}
break;
case 'B' : //Parse BoxLenght Configuration -> Blen,perm
{
ack.type = cmd[0];
char * pch = strtok (cmd,"B");
if( !pch ) return ack;
pch = strtok (pch, "," );
if( !pch ) return ack;
int boxlen = atoi( pch );
pch = strtok (NULL, "," );
if( !pch ) return ack;
int boxperm = atoi( pch );
int err = boxlen_configure( &tck, boxlen, boxperm );
if( err ) return ack;
ack.rp = OK;
// Force Pitlane ON, so "show_cfgpars_onstrip()"
// will show the new values, even if AlwaysON=false
box_init(&tck);
show_cfgpars_onstrip();
}
break;
case 'A' : // Parse Ramp configuration -> Astart,center,end,high,perm
{
ack.type = cmd[0];
char * pch = strtok (cmd,"A");
if( !pch ) return ack;
pch = strtok (pch, "," );
if( !pch ) return ack;
int init = atoi( pch );
pch = strtok (NULL, "," );
if( !pch ) return ack;
int center = atoi( pch );
pch = strtok (NULL, "," );
if( !pch ) return ack;
int end = atoi( pch );
pch = strtok (NULL, ",");
if( !pch ) return ack;
int high = atoi( pch );
pch = strtok (NULL, ",");
if( !pch ) return ack;
int slopeperm = atoi( pch );
int err = ramp_configure( &tck, init, center, end, high, slopeperm );
if( err ) return ack;
ack.rp = OK;
// Force Ramp ON, so "show_cfgpars_onstrip()"
// will show the new values, even if AlwaysON=false
ramp_init(&tck);
show_cfgpars_onstrip();
}
break;
case 'K': // Parse Physic simulation parameters
{
ack.type = cmd[0];
char * pch = strtok (cmd,"K");
if( !pch ) return ack;
pch = strtok (pch, "," );
if( !pch ) return ack;
float kgp = atof( pch );
pch = strtok (NULL, "," );
if( !pch ) return ack;
float kfp = atof( pch );
int err = physic_configure( &tck, kgp, kfp );
if( err ) return ack;
ack.rp = OK;
}
break;
case 'D' : // Load Default Parameters and store them in from EEPROM
{
ack.type = cmd[0];
param_setdefault( &tck.cfg );
EEPROM.put( eeadrInfo, tck.cfg ); // Save immediately
ack.rp = OK;
// Update box/slope active in current Track Struct with values
// just loaded (for show_cfgpars_onstrip())
struct cfgparam const* cfg = &tck.cfg;
tck.boxactive = cfg->track.box_alwaysOn;
tck.rampactive = cfg->ramp.alwaysOn;
show_cfgpars_onstrip();
}
break;
case ':' : // Set board Unique Id
{
struct brdinfo* info = &tck.cfg.info;
ack.type = cmd[0];
if( strlen(cmd + 1) > LEN_UID ) return ack;
strcpy( info->uid, cmd + 1 );
EEPROM.put( eeadrInfo, tck.cfg ); // Save immediately
ack.rp = OK;
}
break;
case '$': // Get Board UID
{
sprintf( txbuff, "%s%s%c", "$", tck.cfg.info.uid, EOL );
serialCommand.sendCommand(txbuff);
ack.rp = NOTHING;
}
break;
case '?' : // Get Software Id
{
sprintf( txbuff, "%s%s%c", "?", softwareId, EOL );
serialCommand.sendCommand(txbuff);
ack.rp = NOTHING;
}
break;
case '%' : // Get Software Version
{
sprintf( txbuff, "%s%s%c", "%", version, EOL );
serialCommand.sendCommand(txbuff);
ack.rp = NOTHING;
}
break;
case 'Q': // Get current configuration Info
{
struct cfgparam const* cfg = &tck.cfg;
sprintf( txbuff, "%s:%d,%d,%d,%d,%d,%d,%d.%03d,%d.%03d%c", "QTRACK",
cfg->track.nled_total,
cfg->track.nled_main,
cfg->track.nled_aux,
cfg->track.init_aux,
cfg->track.box_len,
cfg->track.box_alwaysOn,
(int)cfg->track.kg, (int)(cfg->track.kg*1000)%1000, // std arduino sprintf() missing %f
(int)cfg->track.kf, (int)(cfg->track.kf*1000)%1000, // std arduino sprintf() missing %f
EOL );
serialCommand.sendCommand(txbuff);
sprintf( txbuff, "%s:%d,%d,%d,%d,%d%c", "QRAMP",
cfg->ramp.init,
cfg->ramp.center,
cfg->ramp.end,
cfg->ramp.high,
cfg->ramp.alwaysOn,
EOL );
serialCommand.sendCommand(txbuff);
sprintf( txbuff, "%s:%d,%d,%d,%d%c", "QRACE",
cfg->race.startline,
cfg->race.nlap,
cfg->race.nrepeat,
cfg->race.finishline,
EOL );
serialCommand.sendCommand(txbuff);
ack.rp = NOTHING;
}
break;
case 'W': // Write configuration to EEPROM
{
ack.type = cmd[0];
EEPROM.put( eeadrInfo, tck.cfg );
ack.rp = OK;
}
break;
} // switch
return(ack);
}
/*
*
*/
void sendResponse( ack_t *ack) {
if(ack->type=='\0'){
sprintf(txbuff, "%s%c", ack->rp==OK? "OK":"NOK" , EOL );
} else {
sprintf(txbuff, "%c%s%c", ack->type, ack->rp==OK? "OK":"NOK" , EOL );
}
serialCommand.sendCommand(txbuff);
}
/*
* Send Log/Warning/Error messages to host
*/
void printdebug( const char * msg, int errlevel ) {
char header [5];
sprintf(header, "!%d,",errlevel);
Serial.print(header);
Serial.print(msg);
Serial.print(EOL);
}
/*
* reset race parameters
* stop sound
*/
void enter_configuration_mode(){
noTone(PIN_AUDIO);
strip_clear( &tck );
track.show();
}
void param_load( struct cfgparam* cfg ) {
int cfgversion;
int eeAdress = eeadrInfo;
EEPROM.get( eeAdress, tck.cfg );
eeAdress += sizeof( cfgparam );
EEPROM.get( eeAdress, cfgversion );
sprintf( txbuff, "%s:%d%c", "Parameters Loaded from EEPROM - Cfg ver", cfgversion, EOL );
serialCommand.sendCommand(txbuff);
if ( cfgversion != CFG_VER ) {
param_setdefault( &tck.cfg );
eeAdress = 0;
EEPROM.put( eeAdress, tck.cfg );
eeAdress += sizeof( cfgparam );
EEPROM.put( eeAdress, CFG_VER );
sprintf( txbuff, "%s%c", "DEFAULT PAREMETRS LOADED (and Stored in EEPROM)", EOL );
serialCommand.sendCommand(txbuff);
}
}
/*
* Custon Non-Blocking Delay() functions
* customDelayStart(unsigned long timeout)
* customDelayElapsed
*/
/**
unsigned long customDelay_startTime=0;
unsigned long customDelay_timeout=0;
void customDelayStart(unsigned long tout) {
customDelay_timeout=tout;
customDelay_startTime=millis();
}
boolean customDelayElapsed(){
if((millis() - customDelay_startTime) > customDelay_timeout) {
return(true);
}
return(false);
}
**/
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