Marcus Fisher
IoT Door
Fork of
HUZZAHESP8266-web-control-LPC1768
by 
Austin Dong
main.cpp
- Committer:
- ECE4180
- Date:
- 2017-03-12
- Revision:
- 10:e47b6d245db3
- Parent:
- 9:2259b8443931
File content as of revision 10:e47b6d245db3:
// ESP8266 Static page WEB server to control Mbed
#include "mbed.h"
Serial pc(USBTX, USBRX);
Serial esp(p9, p10); // tx, rx
DigitalOut led1(LED1) ;
DigitalOut led2(LED2) ;
DigitalOut led3(LED3) ;
DigitalOut led4(LED4) ;
DigitalOut door(p23); //Solenoid For Door. 1 = Open
AnalogIn ir_sensor(p19); //Input from IR Sensor
PwmOut speaker(p22); //Speaker Driving Signal
DigitalOut speaker_on(p21); //Turn Speaker and Amp off when not in use, 1=ON
volatile int alarm = 0;
volatile int armed = 0;
int rangecount = 0;
int unlock = 0;
Timer tim;
Timer t_unlock;
Timer t_alarm;
Ticker door_sense;
int alarm_cnt = 0;
// things for sending/receiving data over serial
volatile int tx_in=0;
volatile int tx_out=0;
volatile int rx_in=0;
volatile int rx_out=0;
const int buffer_size = 4095;
char tx_buffer[buffer_size+1];
char rx_buffer[buffer_size+1];
void Tx_interrupt();
void Rx_interrupt();
void send_line();
void read_line();
int DataRX;
int update;
int count;
char cmdbuff[1024];
char replybuff[4096];
char webdata[4096]; // This may need to be bigger depending on WEB browser used
char webbuff[4096]; // Currently using 1986 characters, Increase this if more web page data added
char timebuf[30];
void SendCMD(),getreply(),ReadWebData(),startserver();
void gettime(),setRTC();
char rx_line[1024];
int port =80; // set server port
int SERVtimeout =5; // set server timeout in seconds in case link breaks.
struct tm t;
// manual set RTC values
int minute =00; // 0-59
int hour =12; // 2-23
int dayofmonth =26; // 1-31
int month =8; // 1-12
int year =15; // last 2 digits
void sensorcheck(){
led3 = alarm;
led2 = armed;
speaker_on = 0;
if(armed){
if((alarm == 0) && (ir_sensor.read() > 0.5) && (rangecount < 3)){
if(rangecount == 0) tim.start();
rangecount++;
}
else if(rangecount == 3 && tim.read() > 3 && alarm==0){
alarm = 1;
alarm_cnt++;
rangecount = 0;
t_alarm.start();
}
else if(ir_sensor.read() < 0.5 && alarm == 0){
tim.reset();
rangecount = 0;
}
}
else {alarm = 0;
rangecount = 0;
}
if(alarm){
speaker_on = 1;
speaker = 0.10;
if (t_alarm < 5.0) speaker.period(1.0/969.0);
else if (t_alarm < 10.0) speaker.period(1.0/800.0);
else if (t_alarm >= 10.0) t_alarm.reset();
}
}
int main()
{
pc.baud(9600);
esp.baud(9600);
led1 = 1;
// Setup a serial interrupt function to receive data
esp.attach(&Rx_interrupt, Serial::RxIrq);
// Setup a serial interrupt function to transmit data
esp.attach(&Tx_interrupt, Serial::TxIrq);
if (time(NULL) < 1420070400) {
setRTC();
}
startserver();
DataRX=0;
count=0;
door_sense.attach(&sensorcheck, 1.0);
while(1) {
led4 =! led4;
if(unlock){
t_unlock.start();
door = 1;
if(t_unlock.read() > 3){
door = 0;
t_unlock.reset();
t_unlock.stop();
unlock = 0;
}
}
if(DataRX==1) {
ReadWebData();
esp.attach(&Rx_interrupt, Serial::RxIrq);
}
if(update==1) // update time, hit count, and analog levels in the HUZZAH chip
{
// get new values
gettime();
// send new values
sprintf(cmdbuff, "rangecount,alarm=%d,\"%d\"\r\n",alarm_cnt,alarm);
SendCMD();
getreply();
update=0;
}
}
}
// Reads and processes GET and POST web data
void ReadWebData()
{
wait_ms(200);
esp.attach(NULL,Serial::RxIrq);
DataRX=0;
memset(webdata, '\0', sizeof(webdata));
strcpy(webdata, rx_buffer);
memset(rx_buffer, '\0', sizeof(rx_buffer));
rx_in = 0;
rx_out = 0;
// check web data for form information
if( strstr(webdata, "check=led1v") != NULL ) {
armed =! armed;
}
if( strstr(webdata, "check=led2v") != NULL ) {
unlock= 1;
}
if( strstr(webdata, "check=led3v") != NULL ) {
alarm = 0;
}
if( strstr(webdata, "POST") != NULL ) { // set update flag if POST request
update=1;
}
if( strstr(webdata, "GET") != NULL && strstr(webdata, "favicon") == NULL ) { // set update flag for GET request but do not want to update for favicon requests
update=1;
}
}
// Starts webserver
void startserver()
{
gettime();
pc.printf("++++++++++ Resetting ESP ++++++++++\r\n");
strcpy(cmdbuff,"node.restart()\r\n");
SendCMD();
wait(2);
getreply();
pc.printf("\n++++++++++ Starting Server ++++++++++\r\n> ");
//create server
sprintf(cmdbuff, "srv=net.createServer(net.TCP,%d)\r\n",SERVtimeout);
SendCMD();
getreply();
wait(0.5);
strcpy(cmdbuff,"srv:listen(80,function(conn)\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff,"conn:on(\"receive\",function(conn,payload) \r\n");
SendCMD();
getreply();
wait(0.3);
//print data to mbed
strcpy(cmdbuff,"print(payload)\r\n");
SendCMD();
getreply();
wait(0.2);
//web page data
strcpy(cmdbuff,"conn:send('<!DOCTYPE html><html><body><h1>IoT Door Control</h1>')\r\n");
SendCMD();
getreply();
wait(0.4);
strcpy(cmdbuff,"conn:send('Total Alarm Trips: '..rangecount..'<br><hr>')\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff,"conn:send('Alarm Status: '..alarm..'<br><hr>')\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff,"conn:send('<form method=\"POST\"')\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff, "conn:send('<p><input type=\"checkbox\" name=\"check\" value=\"led1v\"> Arm/Disarm (LED2)')\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff, "conn:send('<p><input type=\"checkbox\" name=\"check\" value=\"led2v\"> Unlock (for 3s)')\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff, "conn:send('<p><input type=\"checkbox\" name=\"check\" value=\"led3v\"> Alarm Off')\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff,"conn:send('<p><input type=\"submit\" value=\"send-refresh\"></form>')\r\n");
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff, "conn:send('<p><h2>How to use:</h2><ul><li>Select a checkbox to flip on/off</li><li>Click Send-Refresh to send data and refresh values</li></ul></body></html>')\r\n");
SendCMD();
getreply();
wait(0.5);
// end web page data
strcpy(cmdbuff, "conn:on(\"sent\",function(conn) conn:close() end)\r\n"); // close current connection
SendCMD();
getreply();
wait(0.3);
strcpy(cmdbuff, "end)\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff, "end)\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff, "tmr.alarm(0, 1000, 1, function()\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff, "if wifi.sta.getip() == nil then\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff, "print(\"Connecting to AP...\\n\")\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff, "else\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff, "ip, nm, gw=wifi.sta.getip()\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff,"print(\"IP Address: \",ip)\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff,"tmr.stop(0)\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff,"end\r\n");
SendCMD();
getreply();
wait(0.2);
strcpy(cmdbuff,"end)\r\n");
SendCMD();
getreply();
wait(0.2);
pc.printf("\n\n++++++++++ Ready ++++++++++\r\n\n");
}
// ESP Command data send
void SendCMD()
{
int i;
char temp_char;
bool empty;
i = 0;
// Start Critical Section - don't interrupt while changing global buffer variables
NVIC_DisableIRQ(UART1_IRQn);
empty = (tx_in == tx_out);
while ((i==0) || (cmdbuff[i-1] != '\n')) {
// Wait if buffer full
if (((tx_in + 1) % buffer_size) == tx_out) {
// End Critical Section - need to let interrupt routine empty buffer by sending
NVIC_EnableIRQ(UART1_IRQn);
while (((tx_in + 1) % buffer_size) == tx_out) {
}
// Start Critical Section - don't interrupt while changing global buffer variables
NVIC_DisableIRQ(UART1_IRQn);
}
tx_buffer[tx_in] = cmdbuff[i];
i++;
tx_in = (tx_in + 1) % buffer_size;
}
if (esp.writeable() && (empty)) {
temp_char = tx_buffer[tx_out];
tx_out = (tx_out + 1) % buffer_size;
// Send first character to start tx interrupts, if stopped
esp.putc(temp_char);
}
// End Critical Section
NVIC_EnableIRQ(UART1_IRQn);
return;
}
// Get Command and ESP status replies
void getreply()
{
read_line();
sscanf(rx_line,replybuff);
}
// Read a line from the large rx buffer from rx interrupt routine
void read_line() {
int i;
i = 0;
// Start Critical Section - don't interrupt while changing global buffer variables
NVIC_DisableIRQ(UART1_IRQn);
// Loop reading rx buffer characters until end of line character
while ((i==0) || (rx_line[i-1] != '\r')) {
// Wait if buffer empty
if (rx_in == rx_out) {
// End Critical Section - need to allow rx interrupt to get new characters for buffer
NVIC_EnableIRQ(UART1_IRQn);
while (rx_in == rx_out) {
}
// Start Critical Section - don't interrupt while changing global buffer variables
NVIC_DisableIRQ(UART1_IRQn);
}
rx_line[i] = rx_buffer[rx_out];
i++;
rx_out = (rx_out + 1) % buffer_size;
}
// End Critical Section
NVIC_EnableIRQ(UART1_IRQn);
rx_line[i-1] = 0;
return;
}
// Interupt Routine to read in data from serial port
void Rx_interrupt() {
DataRX=1;
// Loop just in case more than one character is in UART's receive FIFO buffer
// Stop if buffer full
while ((esp.readable()) && (((rx_in + 1) % buffer_size) != rx_out)) {
rx_buffer[rx_in] = esp.getc();
// Uncomment to Echo to USB serial to watch data flow
pc.putc(rx_buffer[rx_in]);
rx_in = (rx_in + 1) % buffer_size;
}
return;
}
// Interupt Routine to write out data to serial port
void Tx_interrupt() {
// Loop to fill more than one character in UART's transmit FIFO buffer
// Stop if buffer empty
while ((esp.writeable()) && (tx_in != tx_out)) {
esp.putc(tx_buffer[tx_out]);
tx_out = (tx_out + 1) % buffer_size;
}
return;
}
void gettime()
{
time_t seconds = time(NULL);
strftime(timebuf,50,"%H:%M:%S %a %d %b %y", localtime(&seconds));
}
void setRTC()
{
t.tm_sec = (0); // 0-59
t.tm_min = (minute); // 0-59
t.tm_hour = (hour); // 0-23
t.tm_mday = (dayofmonth); // 1-31
t.tm_mon = (month-1); // 0-11 "0" = Jan, -1 added for Mbed RCT clock format
t.tm_year = ((year)+100); // year since 1900, current DCF year + 100 + 1900 = correct year
set_time(mktime(&t)); // set RTC clock
}