Benjamin Leverett
Ben with semaphore test 1
Dependencies: mbed mbed-rtos 4DGL-uLCD-SE SDFileSystem ATParser
main.cpp
- Committer:
- bleverett3
- Date:
- 2020-04-24
- Revision:
- 7:9b36eb4811eb
- Parent:
- 6:be33395fe424
File content as of revision 7:9b36eb4811eb:
#include "mbed.h"
#include "rtos.h"
#include "ATParser.h"
#include "uLCD_4DGL.h"
#include "SDFileSystem.h"
#include "Speaker.h"
//#include "wave_player.h"
#include <string>
#include <iostream>
using namespace std;
//General setups
DigitalOut cmdMode(p18);
Serial pc(USBTX, USBRX);
BufferedSerial ble(p13,p14);
DigitalOut cmdstuff(p18);
DigitalOut greenLED(p24);
DigitalOut yellowLED(p25);
DigitalOut redLED(p26);
uLCD_4DGL uLCD(p28,p27,p30);
SDFileSystem sd(p5, p6, p7, p8, "sd");
Semaphore sem(0);
//Speaker mySpeaker(p21);
//AT command data handlers
bool datalogged = 0;
char delimiter[] = "\r\n";
int buffer_size = 256;
int timeout = 100;
bool debug = false;
ATParser at(ble, delimiter, buffer_size, timeout, debug);
char buffer[10];
volatile int risk_level = 0;
int temp_risk = -1;
int changed = 0;
//RTOS Mutex Lock
Mutex mutex_lock;
Mutex lcd_lock;
//Global Data points and arrays
int averageCount = 0;
volatile int RSSI_array[15];
//This portion of the code handles RSSI readings
int calculate_average(volatile int *input, int size)
{
int average;
for(int i = 0; i< size; i++) {
average = average + input[i];
}
average = average/size;
return average;
}
void parse_RSSI()
{
mutex_lock.lock();
at.send("AT+BLEGETRSSI") && at.read(buffer, 10);
if(buffer[0] == '-') {
//datalogged = 1;
pc.printf("RSSI: ");
pc.putc(buffer[1]);
pc.putc(buffer[2]);
pc.printf("\n");
int digit1 = buffer[1] - 48;
int digit2 = buffer[2] - 48;
int total = 10*digit1 + digit2;
if (averageCount <= 15) {
RSSI_array[averageCount] = total;
}
averageCount++;
if(averageCount > 15 && buffer[0] == '-') {
averageCount = 0;
int average = calculate_average(RSSI_array, 15);
if(average < 55) {
temp_risk = 3;
} else if(average > 55 && average < 70) {
temp_risk = 2;
} else if(average > 70 && average < 90) {
temp_risk = 1;
} else {
temp_risk = 0;
}
if(risk_level != temp_risk) {
risk_level = temp_risk;
changed = 1;
}
}
pc.printf("Risk level: ");
pc.printf("%i\n", risk_level);
} else {
pc.printf("Disconnected\n");
datalogged = 0;
}
mutex_lock.unlock();
}
//This portion of the code handles peripherals
/*
void speaker_alarm()
{
while(1){
if(risk_level >= 2 && datalogged){
mySpeaker.PlayNote(969.0, 0.5, 1.0);
mySpeaker.PlayNote(800.0, 0.5, 1.0);
}else{
mySpeaker.PlayNote(0.0, 0.0, 0.0);
}
}
}
*/
void logging_SD_card()
{
}
void blink_leds()
{
while(1){
if(risk_level <= 1){
greenLED = 1;
redLED = 0;
yellowLED = 0;
}else if(risk_level == 2){
yellowLED = 1;
greenLED = 0;
redLED = 0;
}else if(risk_level == 3){
redLED = 1;
yellowLED = 0;
greenLED = 0;
}else{
redLED = 0;
yellowLED = 0;
greenLED = 0;
}
}
}
void display_ulcd()
{
mutex_lock.lock();
uLCD.color(WHITE);
mutex_lock.unlock();
while(1){
mutex_lock.lock();
if (changed) {
if(risk_level <= 1){
uLCD.cls();
uLCD.locate(5, 7);
uLCD.text_width(2);
uLCD.text_height(2);
uLCD.background_color(GREEN);
uLCD.textbackground_color(GREEN);
uLCD.printf("Safe");
}else if(risk_level == 2){
uLCD.cls();
uLCD.locate(1, 7);
uLCD.text_width(2);
uLCD.text_height(2);
uLCD.background_color(0xFFFF00);
uLCD.textbackground_color(0xFFFF00);
uLCD.printf("Cautious");
}else if(risk_level == 3){
uLCD.cls();
uLCD.locate(3, 7);
uLCD.text_width(2);
uLCD.text_height(2);
uLCD.background_color(RED);
uLCD.textbackground_color(RED);
uLCD.printf("Hazard");
}else{
uLCD.background_color(BLACK);
uLCD.printf("waiting");
}
changed = 0;
}
mutex_lock.unlock();
}
}
int main()
{
cmdstuff = 1;
at.send("AT") && at.recv("OK");
at.send("AT+AB ChangeDefaultBaud [9600]", 3) && at.recv("OK");
pc.baud(9600);
ble.baud(9600);
//Thread SD_Thread();
Thread ULCD_Thread(display_ulcd);
Thread LED_Thread(blink_leds);
//Thread Speaker_Thread(speaker_alarm);
while(1) {
parse_RSSI();
}
}