mstroh76 4 miesięcy temu
rodzic
commit
66bbc3a6a9
2 zmienionych plików z 169 dodań i 0 usunięć
  1. +159
    -0
      wiringPi/test/wiringpi_test9_pwm.c
  2. +10
    -0
      wiringPi/test/wpi_test.h

+ 159
- 0
wiringPi/test/wiringpi_test9_pwm.c Wyświetl plik

@@ -0,0 +1,159 @@
// WiringPi test program: PWM test
// Compile: gcc -Wall wiringpi_test9_pwm.c -o wiringpi_test9_pwm -lwiringPi

#include "wpi_test.h"
#include <string.h>
#include <errno.h>
#include <unistd.h>
#include <sys/time.h>
#include <time.h>
#include <stdint.h>


int PWM0 = 12;
int FREQIN = 6;

volatile int gCounter = 0;

//Interrupt Service Routine for FREQIN
void ISR_FREQIN(void) {
gCounter++;
}

double MeasureAndCheckFreq(const char* msg, double expect_freq) {
double fFrequency;
clock_t CPUClockBegin, CPUClockEnd;
int CountBegin, CountEnd;
double CPUClockInterval, CountInterval;
double elapsed_time, CPULoad;
uint64_t tbegin, tend;
int SleepMs = 1200;

CPUClockBegin = clock();
tbegin = piMicros64();
CountBegin = gCounter;
delay(SleepMs);
CountEnd = gCounter;
CPUClockEnd = clock();
tend = piMicros64();

elapsed_time = (double)(tend-tbegin)/1.0e6;
CountInterval = CountEnd - CountBegin;
CPUClockInterval = CPUClockEnd - CPUClockBegin;
CPULoad = CPUClockInterval*100.0 / CLOCKS_PER_SEC / elapsed_time;
fFrequency = CountInterval / elapsed_time / 1000;

printf("Interval: time: %.6f sec (CPU: %3.1f %%), count: %g -> frequency: %.3f kHz\n",
elapsed_time, CPULoad, CountInterval, fFrequency);

CheckSameDouble("Wait for freq. meas.", elapsed_time, SleepMs/1000.0, 0.1); //100ms tolerance. maybe problematic on high freq/cpu load
CheckSameDouble(msg, fFrequency, expect_freq, expect_freq*2/100); //2% tolerance

return fFrequency;
}


int tests_pwmc[7] = {1456, 1000, 512, 100, 2000, 3000, 4000};
int tests_duty[7] = { 512, 768, 682, 922, 256, 341, 102};
int tests_pwmr[10]= { 100, 512, 1024, 1456, 2000, 3000, 5000, 10000, 15000, 20000};

int main (void) {

int major, minor;
char msg[255];

wiringPiVersion(&major, &minor);

printf("WiringPi GPIO test program 9 (using PWM@GPIO%d (output) and GPIO%d (input))\n", PWM0, FREQIN);
printf(" pwm0 irq time\n");

printf("\nPWM/ISR test (WiringPi %d.%d)\n", major, minor);

wiringPiSetupGpio() ;

int rev, mem, maker, overVolted, RaspberryPiModel;
piBoardId(&RaspberryPiModel, &rev, &mem, &maker, &overVolted);
CheckNotSame("Model: ", RaspberryPiModel, -1);

if (!piBoard40Pin()) {
PWM0 = 18;
FREQIN = 17;
}
// INT_EDGE_BOTH, INT_EDGE_FALLING, INT_EDGE_RISING only one ISR per input
int result = wiringPiISR(FREQIN, INT_EDGE_RISING, &ISR_FREQIN);
CheckSame("Register ISR", result, 0);
if (result < 0) {
printf("Unable to setup ISR for GPIO %d (%s)\n\n",
FREQIN, strerror(errno));
return UnitTestState();
}

int Pi4 = 0;
switch(RaspberryPiModel) {
case PI_MODEL_4B:
case PI_MODEL_400:
case PI_MODEL_CM4:
case PI_MODEL_CM4S:
Pi4 = 1;
break;
case PI_MODEL_5:
return UnitTestState(); //not supported so far
}

printf("\nPWM0 BAL mode:\n");
printf("==============\n");

pinMode(PWM0, PWM_OUTPUT); //pwmr=1024, pwmc=32
const int pmw = 512;
int pmwr = 1024;
pwmWrite(PWM0, pmw); //50% Duty
//MeasureAndCheckFreq("50\% Duty (default)", 300.000); //FAIL , freq (pwmc=32) to high for irq count

for (int c_duty=0, c_duty_end = sizeof(tests_duty)/sizeof(tests_duty[0]); c_duty<c_duty_end; c_duty++) {

double tests_duty_corr;
if (tests_duty[c_duty]>(pmwr/2)) {
tests_duty_corr = pmwr-tests_duty[c_duty];
} else {
tests_duty_corr = tests_duty[c_duty];
}

double duty_fact = tests_duty_corr/(double)pmwr;
printf("\n%d/%d set duty %d/%d\n",c_duty+1, c_duty_end, tests_duty[c_duty], pmwr);
pwmWrite(PWM0, tests_duty[c_duty]);

for (int c_pwmc=0, end = sizeof(tests_pwmc)/sizeof(tests_pwmc[0]); c_pwmc<end; c_pwmc++) {
if (Pi4 && tests_pwmc[c_pwmc]>1456) {
printf("* Set Clock (pwmc) %d not possible on BCM2711 system (OSC 54 MHz), ignore\n", tests_pwmc[c_pwmc]);
continue;
}
pwmSetClock(tests_pwmc[c_pwmc]);
delay(250);
double freq = 19200.0/tests_pwmc[c_pwmc]*duty_fact;
sprintf(msg, "Set Clock (pwmc) %d, %d%% duty", tests_pwmc[c_pwmc], tests_duty[c_duty]*100/pmwr);
MeasureAndCheckFreq(msg, freq);
}

}

delay(250);
pwmSetMode(PWM_MODE_MS) ;
printf("\nPWM0 MS mode:\n");
printf("==============\n");

int pwmc = 10;
pwmSetClock(pwmc);
delay(2500);

for (int c_pmwr=0, c_pmwr_end = sizeof(tests_pwmr)/sizeof(tests_pwmr[0]); c_pmwr<c_pmwr_end; c_pmwr++) {
pwmWrite(PWM0, tests_pwmr[c_pmwr]/2);
pwmSetRange(tests_pwmr[c_pmwr]) ;
delay(250);
double freq = 19200.0/(double)pwmc/(double)tests_pwmr[c_pmwr];
sprintf(msg, "Set range (pwmr) %d", tests_pwmr[c_pmwr]);
MeasureAndCheckFreq(msg, freq);
}


return UnitTestState();
}

+ 10
- 0
wiringPi/test/wpi_test.h Wyświetl plik

@@ -105,6 +105,16 @@ void CheckSameFloat(const char* msg, float value, float expect) {
}


void CheckSameDouble(const char* msg, double value, double expect, double epsilon) {
if (fabs(value-expect)<epsilon) {
printf("%35s (%.3f==%.3f) -> %spassed%s \n", msg, value, expect, COLORGRN, COLORDEF);
} else {
printf("%35s (%.3f<>%.3f) -> %sfailed%s \n" , msg, value, expect, COLORRED, COLORDEF);
globalError=1;
}
}


int UnitTestState() {
printf("\n\nUNIT TEST STATE: ");
if (globalError) {


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