local timers
Dependencies: TextLCD mbed-rtos mbed
Fork of pacemaker_FINAL_v2 by
main.cpp
- Committer:
- jfields
- Date:
- 2014-12-04
- Revision:
- 4:584d9e2e4fae
- Parent:
- 3:c60266d9ce0b
- Child:
- 5:8cd62e3c3c3a
File content as of revision 4:584d9e2e4fae:
#include "constants.h" // global clocks Timer t; // global time int waitingForV = 1; // mutexes Mutex status_mutex; // protect reading of Mutex input_mutex; // protects reading input Mutex man_mutex; // protects manual Mutex state_mutex; // protects waitingForV // functions void A_func(void const *args); void V_func(void const *args); void manage_flags(void const *i); void flashLED(int i); void calcHR(void const *args); void disp(void const *args); void input_func(void const *args); void setVals(char c); void makeManual(); void blind(); void get_listener(void const *args); void updateSR(); // threads Thread * A_thread; Thread * V_thread; Thread * input_thread; Thread * disp_thread; Thread * listener; // rtos timers RtosTimer * VRP_timer; RtosTimer * PVARP_timer; RtosTimer * HR_timer; int main() { // start global timer t.start(); // init threads disp_thread = new Thread(disp); input_thread = new Thread(input_func); A_thread = new Thread(A_func); V_thread = new Thread(V_func); listener = new Thread(get_listener); // init timers VRP_timer = new RtosTimer(manage_flags, osTimerOnce, (void *)1); PVARP_timer = new RtosTimer(manage_flags, osTimerOnce, (void *)2); HR_timer = new RtosTimer(calcHR, osTimerPeriodic, (void *)0); // start display and heart rate sample HR_timer->start(sampleRate); disp_thread->signal_set(RUN); // main thread while (1) { } } void A_func(void const *args) { while (1) { man_mutex.lock(); if (!inManual) { state_mutex.lock(); if (!waitingForV) { if (t.read_ms() >= LRI-AVI) { t.reset(); waitingForV = 1; APace = 1; Thread::wait(2); APace = 0; flashLED(2); } if (AGet == 1 && !isPVARP) { t.reset(); waitingForV = 1; flashLED(4); } } state_mutex.unlock(); } man_mutex.unlock(); } } void V_func(void const *args) { while (1) { man_mutex.lock(); if (!inManual) { state_mutex.lock(); if (waitingForV) { if (t.read_ms() >= AVI) { t.reset(); VPace = 1; Thread::wait(2); VPace = 0; blind(); flashLED(1); } if (VGet == 1 && !isVRP) { t.reset(); blind(); flashLED(3); } } state_mutex.unlock(); } man_mutex.unlock(); } } void input_func(void const *args) { while (1) { input_mutex.lock(); input=pc.getc(); if (input == 'n') setVals('n'); if (input == 's') setVals('s'); if (input == 'e') setVals('e'); if (input == 'm') makeManual(); if (input == 'o') { lcd.printf("Enter\n\n"); Omode = 1; input = pc.getc(); if (input == '1') { sampleRate = 10000; updateSR(); } if (input == '2') { sampleRate = 20000; updateSR(); } if (input == '3') { sampleRate = 30000; updateSR(); } if (input == '4') { sampleRate = 60000; updateSR(); } if (input == '5') { sampleRate = 100000; updateSR(); } } input_mutex.unlock(); } } void calcHR(void const *args) { status_mutex.lock(); if (firstSample == 1) { HR = beats*(60000/sampleRate); firstSample = 0; } else { HR = (beats*60000/sampleRate+HR)/2; } if (HR>=UB || HR<=LB) { speaker.period(1.0/500.0); // 500hz period speaker =0.5; } else { speaker=0.0; } status_mutex.unlock(); disp_thread->signal_set(RUN); } void disp(void const *args) { while (1) { Thread::signal_wait(RUN,osWaitForever); status_mutex.lock(); if (!Omode) { lcd.printf("HR = %d ppm\nCycle = %d s\n",HR,sampleRate/1000); } beats = 0; status_mutex.unlock(); } } void manage_flags(void const *i) { status_mutex.lock(); if ((int)i==1) isVRP = 0; if ((int)i==2) isPVARP = 0; status_mutex.unlock(); } void flashLED(int i) { leds[i-1] = 1; wait(0.01); leds[i-1] = 0; } void blind() { status_mutex.lock(); isVRP = 1; isPVARP = 1; waitingForV = 0; VRP_timer->start(VRP); PVARP_timer->start(PVARP); beats++; status_mutex.unlock(); } void makeManual() { man_mutex.lock(); inManual = 1; man_mutex.unlock(); UB = 175; LB = 30; int done = 0; while (!done) { input = pc.getc(); if (input == 'v') { VPace = 1; Thread::wait(2); VPace = 0; flashLED(1); } if (input == 'a') { APace = 1; Thread::wait(2); APace = 0; flashLED(2); } if (input == 's') { setVals('s'); done = 1; } if (input == 'e') { setVals('s'); done = 1; } if (input == 'n') { setVals('s'); done = 1; } if (input == 'o') { lcd.printf("Enter\n\n"); Omode = 1; input = pc.getc(); if (input == '1') { sampleRate = 10000; updateSR(); } if (input == '2') { sampleRate = 20000; updateSR(); } if (input == '3') { sampleRate = 30000; updateSR(); } if (input == '4') { sampleRate = 60000; updateSR(); } if (input == '5') { sampleRate = 100000; updateSR(); } } } waitingForV = 1; VRP_timer->stop(); PVARP_timer->stop(); man_mutex.lock(); inManual = 0; man_mutex.unlock(); } void get_listener(void const *args) { while (1) { if (inManual) { if (AGet == 1) { flashLED(4); while (AGet == 1); } if (VGet == 1) { flashLED(3); while (VGet == 1); } } } } void setVals(char c) { if (c == 'n') { PVARP = N_PVARP; VRP = N_VRP; LRI = N_LRI; AVI = N_AVI; UB = N_UB; LB = N_LB; } if (c == 's') { PVARP = S_PVARP; VRP = S_VRP; LRI = S_LRI; AVI = S_AVI; UB = S_UB; LB = S_LB; } if (c == 'e') { PVARP = E_PVARP; VRP = E_VRP; LRI = E_LRI; AVI = E_AVI; UB = E_UB; LB = E_LB; } } void updateSR() { status_mutex.lock(); beats = 0; HR = 0; Omode = 0; firstSample = 1; HR_timer->stop(); HR_timer->start(sampleRate); status_mutex.unlock(); disp_thread->signal_set(RUN); }