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// Program to test the timer.h implementation's essential functionality.
#include "wirish.h"
#include "timer.h"
void handler1(void);
void handler2(void);
void handler3(void);
void handler4(void);
void handler3b(void);
void handler4b(void);
int t;
int count1 = 0;
int count2 = 0;
int count3 = 0;
int count4 = 0;
uint16 rate1 = 1000;
uint16 rate2 = 2000;
uint16 rate3 = 4000;
uint16 rate4 = 8000;
uint16 val1 = 10000;
uint16 val2 = 10000;
uint16 val3 = 10000;
uint16 val4 = 10000;
// FIXME [0.1.0] high density timer test (especially basic timers + DAC)
timer_dev *timers[] = {TIMER1, TIMER2, TIMER3, TIMER4};
voidFuncPtr handlers[] = {handler1, handler2, handler3, handler4};
void initTimer(timer_dev *dev);
void setTimerPeriod(timer_dev *dev, uint32 period_us);
void testSetTimerPeriod(uint32 period);
void testTimerChannels(timer_dev *dev);
int timerNumber(timer_dev *dev);
void setup() {
// Set up the LED to blink
pinMode(BOARD_LED_PIN, OUTPUT);
// Setup the button as input
pinMode(BOARD_BUTTON_PIN, INPUT);
// Send a message out Serial2
Serial2.begin(115200);
Serial2.println("*** Initializing timers...");
timer_foreach(initTimer);
Serial2.println("*** Done. Beginning timer test.");
}
void loop() {
Serial2.println("-----------------------------------------------------");
Serial2.println("Testing timer_get_count()/timer_set_count()");
Serial2.print("TIMER1 count = ");
Serial2.println(timer_get_count(TIMER1));
Serial2.println("timer_set_count(TIMER1, 1234)");
timer_set_count(TIMER1, 1234);
Serial2.print("timer_get_count(TIMER1) = ");
Serial2.println(timer_get_count(TIMER1));
Serial2.println("-----------------------------------------------------");
Serial2.println("Testing pause/resume; button roughly controls TIMER4");
// when BUT is held down, TIMER4 is in the "pause" state and the
// timer doesn't increment, so the final counts should reflect the
// ratio of time that BUT was held down.
count3 = 0;
count4 = 0;
timer_set_mode(TIMER3, TIMER_CH1, TIMER_OUTPUT_COMPARE);
timer_set_mode(TIMER4, TIMER_CH1, TIMER_OUTPUT_COMPARE);
timer_pause(TIMER3);
timer_pause(TIMER4);
timer_set_count(TIMER3, 0);
timer_set_count(TIMER4, 0);
timer_set_reload(TIMER3, 30000);
timer_set_reload(TIMER4, 30000);
timer_set_compare(TIMER3, 1, 1000);
timer_set_compare(TIMER4, 1, 1000);
timer_attach_interrupt(TIMER3, TIMER_CC1_INTERRUPT, handler3b);
timer_attach_interrupt(TIMER4, TIMER_CC1_INTERRUPT, handler4b);
timer_resume(TIMER3);
timer_resume(TIMER4);
Serial2.println("Testing for ~4 seconds...");
for(int i = 0; i < 4000; i++) {
if (isButtonPressed()) {
timer_pause(TIMER4);
} else {
timer_resume(TIMER4);
}
delay(1);
}
timer_set_mode(TIMER3, TIMER_CH1, TIMER_DISABLED);
timer_set_mode(TIMER4, TIMER_CH1, TIMER_DISABLED);
Serial2.print("TIMER3 count: ");
Serial2.println(timer_get_count(TIMER3));
Serial2.print("TIMER4 count: ");
Serial2.println(timer_get_count(TIMER4));
Serial2.println("-----------------------------------------------------");
Serial2.println("Testing setTimerPeriod()");
testSetTimerPeriod(10);
testSetTimerPeriod(30000);
testSetTimerPeriod(300000);
testSetTimerPeriod(30000);
Serial2.println("Sanity check (with hand-coded reload and prescaler for "
"72 MHz timers):");
timer_set_mode(TIMER4, TIMER_CH1, TIMER_OUTPUT_COMPARE);
timer_set_prescaler(TIMER4, 33);
timer_set_reload(TIMER4, 65454);
timer_pause(TIMER4);
timer_set_count(TIMER4, 0);
timer_set_compare(TIMER4, TIMER_CH1, 1);
timer_attach_interrupt(TIMER4, TIMER_CC1_INTERRUPT, handler4b);
Serial2.println("Period 30000ms, wait 2 seconds...");
count4 = 0;
timer_resume(TIMER4);
delay(2000);
timer_pause(TIMER4);
timer_set_mode(TIMER4, TIMER_CH1, TIMER_DISABLED);
Serial2.print("TIMER4 count: ");
Serial2.println(count4);
Serial2.println(" (Should be around 2sec/30000ms ~ 67)");
// Test all the individual timer channels
timer_foreach(testTimerChannels);
}
void initTimer(timer_dev *dev) {
switch (dev->type) {
case TIMER_ADVANCED:
case TIMER_GENERAL:
Serial2.print("Initializing timer ");
Serial2.println(timerNumber(dev));
for (int c = 1; c <= 4; c++) {
timer_set_mode(dev, c, TIMER_OUTPUT_COMPARE);
}
Serial2.println("Done.");
break;
case TIMER_BASIC:
break;
}
}
void testSetTimerPeriod(uint32 period) {
timer_set_mode(TIMER4, TIMER_CH1, TIMER_OUTPUT_COMPARE);
timer_set_compare(TIMER4, TIMER_CH1, 1);
setTimerPeriod(TIMER4, period);
timer_pause(TIMER4);
timer_set_count(TIMER4, 0);
timer_attach_interrupt(TIMER4, TIMER_CC1_INTERRUPT, handler4b);
Serial2.println("Period ");
Serial2.print(period);
Serial2.print(" ms. Waiting 2 seconds...");
count4 = 0;
timer_resume(TIMER4);
delay(2000);
timer_pause(TIMER4);
timer_set_mode(TIMER4, TIMER_CH1, TIMER_DISABLED);
Serial2.print("TIMER4 count: ");
Serial2.println(timer_get_count(TIMER4));
Serial2.print(" (Should be around 2 sec / ");
Serial2.print(period);
Serial2.print(" ms = ");
Serial2.print(double(2) / period * 1000);
Serial2.println(", modulo delays due to interrupts)");
}
int timerNumber(timer_dev *dev) {
switch (dev->clk_id) {
case RCC_TIMER1:
return 1;
case RCC_TIMER2:
return 2;
case RCC_TIMER3:
return 3;
case RCC_TIMER4:
return 4;
#ifdef STM32_HIGH_DENSITY
case RCC_TIMER5:
return 5;
case RCC_TIMER6:
return 6;
case RCC_TIMER7:
return 7;
case RCC_TIMER8:
return 8;
#endif
default:
ASSERT(0);
return 0;
}
}
/* This function touches every channel of a given timer. The output
* ratios should reflect the ratios of the rate variables. It
* demonstrates that, over time, the actual timing rates get blown
* away by other system interrupts. */
void testTimerChannels(timer_dev *dev) {
t = timerNumber(dev);
toggleLED();
delay(100);
Serial2.println("-----------------------------------------------------");
switch (dev->type) {
case TIMER_BASIC:
Serial2.print("NOT testing channels for basic timer ");
Serial2.println(t);
break;
case TIMER_ADVANCED:
case TIMER_GENERAL:
Serial2.print("Testing channels for timer ");
Serial2.println(t);
timer_pause(dev);
count1 = count2 = count3 = count4 = 0;
timer_set_reload(dev, 0xFFFF);
timer_set_prescaler(dev, 1);
for (int c = 1; c <= 4; c++) {
timer_set_compare(dev, c, 65535);
timer_set_mode(dev, c, TIMER_OUTPUT_COMPARE);
timer_attach_interrupt(dev, c, handlers[c - 1]);
}
timer_resume(dev);
delay(3000);
for (int c = 1; c <= 4; c++) {
timer_set_mode(dev, c, TIMER_DISABLED);
}
Serial2.print("Channel 1 count: "); Serial2.println(count1);
Serial2.print("Channel 2 count: "); Serial2.println(count2);
Serial2.print("Channel 3 count: "); Serial2.println(count3);
Serial2.print("Channel 4 count: "); Serial2.println(count4);
break;
}
}
// FIXME [0.1.0] move some incarnation of this into timer.h
void setTimerPeriod(timer_dev *dev, uint32 period_us) {
if (!period_us) {
// FIXME handle this case
ASSERT(0);
return;
}
uint32 cycles = period_us * CYCLES_PER_MICROSECOND;
uint16 pre = (uint16)((cycles >> 16) + 1);
timer_set_prescaler(dev, pre);
timer_set_reload(dev, cycles / pre - 1);
}
void handler1(void) {
val1 += rate1;
timer_set_compare(timers[t], TIMER_CH1, val1);
count1++;
}
void handler2(void) {
val2 += rate2;
timer_set_compare(timers[t], TIMER_CH2, val2);
count2++;
}
void handler3(void) {
val3 += rate3;
timer_set_compare(timers[t], TIMER_CH3, val3);
count3++;
}
void handler4(void) {
val4 += rate4;
timer_set_compare(timers[t], TIMER_CH4, val4);
count4++;
}
void handler3b(void) {
count3++;
}
void handler4b(void) {
count4++;
}
__attribute__((constructor)) void premain() {
init();
}
int main(void) {
setup();
while (true) {
loop();
}
return 0;
}
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