pigpio/checklib.c

710 lines
18 KiB
C

/*
This is free and unencumbered software released into the public domain.
Anyone is free to copy, modify, publish, use, compile, sell, or
distribute this software, either in source code form or as a compiled
binary, for any purpose, commercial or non-commercial, and by any
means.
In jurisdictions that recognize copyright laws, the author or authors
of this software dedicate any and all copyright interest in the
software to the public domain. We make this dedication for the benefit
of the public at large and to the detriment of our heirs and
successors. We intend this dedication to be an overt act of
relinquishment in perpetuity of all present and future rights to this
software under copyright law.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR
OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
OTHER DEALINGS IN THE SOFTWARE.
For more information, please refer to <http://unlicense.org/>
*/
/*
This version is for pigpio version 3+
*/
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <sys/time.h>
#include <time.h>
#include "pigpio.h"
#define GREENLED 16
#define SDDET 47
#define SDCLK 48
int test =1;
int passes=0;
int expect=0;
struct timeval libInitTime;
int GPIO=4;
unsigned inited, count, onMicros, offMicros;
void tick(void)
{
/* count ticks
*/
static struct timeval lastTime;
struct tm tmp;
struct timeval nowTime;
char buf[32];
gettimeofday(&nowTime, NULL);
localtime_r(&nowTime.tv_sec, &tmp);
strftime(buf, sizeof(buf), "%F@%T", &tmp);
printf("%s.%03d\n", buf, (int)nowTime.tv_usec/1000);
/*timersub(&nowTime, &lastTime, &diffTime);*/
lastTime = nowTime;
if (inited)
{
count++;
}
else
{
count = 1;
gettimeofday(&lastTime, NULL);
inited = 1;
}
}
void tickEx(void * userdata)
{
}
void alert(int gpio, int level, uint32_t tick)
{
/* accumulate number of level changes and average time gpio
was on and off. Hopefully the ratio should reflect the
selected pulsewidth.
*/
static uint32_t lastTick;
uint32_t diffTick;
if (inited)
{
count++;
diffTick = tick - lastTick;
if (level == 0)
{
/* elapsed time was on */
onMicros = onMicros + diffTick;
}
else
{
/* elapsed time was off */
offMicros = offMicros + diffTick;
}
lastTick = tick;
}
else
{
count = 1;
lastTick = tick;
onMicros = 0;
offMicros = 0;
inited = 1;
}
}
void alertEx(int gpio, int level, uint32_t tick, void * userdata)
{
}
static void timerTest(unsigned waitfor, unsigned ms)
{
unsigned ep, ep1, ep2;
ep= (waitfor*1000)/ms; ep1=ep-1; ep2=ep+1;
printf("Timer ticktest (%d ms), wait %d seconds\n", ms, waitfor);
printf("Expect %d to %d ticks\n", ep1, ep2);
inited = 0;
gpioSetTimerFunc(0, ms, tick);
sleep(waitfor);
gpioSetTimerFunc(0, ms, NULL);
/* and the stats were? */
printf("ticks=%d\n", count);
if ((count>=ep1) && (count<=ep2))
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else
{
printf("TEST %d: FAILED\n\n", test);
}
++test;
}
static void servoTest(unsigned waitfor, unsigned pulsewidth)
{
int ticks, on, off;
unsigned expectedPulses, ep1, ep2;
float expectedRatio, er1, er2;
float ratio;
expectedPulses=(500*waitfor)/10; ep1=(490*waitfor)/10; ep2=(510*waitfor)/10;
expectedRatio = (float)(20000-pulsewidth)/(float)pulsewidth;
er1=expectedRatio*0.9; er2=expectedRatio*1.1;
printf("Servo pulse test (%d micros), wait %d seconds\n",
pulsewidth, waitfor);
printf("Expect %d pulses and an off/on ratio of %.1f\n",
expectedPulses, expectedRatio);
gpioServo(GPIO, pulsewidth);
inited = 0;
gpioSetAlertFunc(GPIO, alert);
sleep(waitfor);
gpioSetAlertFunc(GPIO, NULL);
gpioServo(GPIO, 0);
/* and the stats were? */
ticks = count/2; on = onMicros/1000; off = offMicros/1000;
ratio = (float)off/(float)on;
printf("servo pulses=%d on ms=%d off ms=%d ratio=%.1f\n", ticks, on, off, ratio);
if ( ((ticks>ep1) && (ticks<ep2)) && ((ratio>er1) && (ratio<er2)) )
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else
{
printf("TEST %d: FAILED\n\n", test);
}
++test;
}
static void pwmTest(unsigned waitfor, unsigned pulsewidth)
{
int on, off;
float expectedRatio, er1, er2;
float ratio;
expectedRatio = (float)(255-pulsewidth)/255.0;
er1=expectedRatio*0.9; er2=expectedRatio*1.1;
printf("PWM test (%d), wait %d seconds\n", pulsewidth, waitfor);
printf("Expect an off/on ratio of %.3f\n", expectedRatio);
inited = 0;
gpioSetAlertFunc(GPIO, alert);
gpioPWM(GPIO, pulsewidth);
sleep(waitfor);
gpioPWM(GPIO, 0);
gpioSetAlertFunc(GPIO, NULL);
/* and the stats were? */
on = onMicros/1000; off = offMicros/1000;
ratio = (float)off/((float)on+(float)off);
printf("pwm on ms=%d off ms=%d ratio=%.3f\n", on, off, ratio);
if ((ratio>er1) && (ratio<er2))
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else
{
printf("TEST %d: FAILED\n\n", test);
}
++test;
}
void expectExpected(int expected)
{
if (expect==expected)
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else printf("TEST %d: FAILED\n\n", test);
expect = 0;
++test;
}
void checkValidation(void)
{
int secs, micros;
/* check function parameter validation */
printf("Function parameter validation tests\n");
printf("Expect ERROR messages\n\n");
if (gpioSetMode(PI_MAX_GPIO+1, 0) == PI_BAD_GPIO) expect++;
if (gpioSetMode(PI_MIN_GPIO-1, 0) == PI_BAD_GPIO) expect++;
if (gpioSetMode(PI_MIN_GPIO, PI_ALT3+1) == PI_BAD_MODE) expect++;
if (gpioSetMode(PI_MAX_GPIO, PI_INPUT-1) == PI_BAD_MODE) expect++;
expectExpected(4);
if (gpioGetMode(PI_MAX_GPIO+1) == PI_BAD_GPIO) expect++;
if (gpioGetMode(PI_MIN_GPIO-1) == PI_BAD_GPIO) expect++;
expectExpected(2);
if (gpioSetPullUpDown(PI_MAX_GPIO+1, 0) == PI_BAD_GPIO) expect++;
if (gpioSetPullUpDown(PI_MIN_GPIO-1, 0) == PI_BAD_GPIO) expect++;
if (gpioSetPullUpDown(PI_MIN_GPIO, PI_PUD_UP+1) == PI_BAD_PUD) expect++;
if (gpioSetPullUpDown(PI_MAX_GPIO, PI_PUD_OFF-1) == PI_BAD_PUD) expect++;
expectExpected(4);
if (gpioRead(PI_MIN_GPIO-1) == PI_BAD_GPIO) expect++;
if (gpioRead(PI_MAX_GPIO+1) == PI_BAD_GPIO) expect++;
expectExpected(2);
if (gpioWrite(PI_MAX_GPIO+1, 0) == PI_BAD_GPIO) expect++;
if (gpioWrite(PI_MIN_GPIO-1, 0) == PI_BAD_GPIO) expect++;
if (gpioWrite(PI_MIN_GPIO, PI_ON+1) == PI_BAD_LEVEL) expect++;
if (gpioWrite(PI_MAX_GPIO, PI_OFF-1) == PI_BAD_LEVEL) expect++;
expectExpected(4);
if (gpioPWM(PI_MAX_USER_GPIO+1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioPWM(PI_MIN_GPIO-1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioPWM(PI_MIN_GPIO, PI_DEFAULT_DUTYCYCLE_RANGE+1) ==
PI_BAD_DUTYCYCLE) expect++;
if (gpioPWM(PI_MAX_USER_GPIO, -1) == PI_BAD_DUTYCYCLE) expect++;
expectExpected(4);
if (gpioSetPWMrange(PI_MAX_USER_GPIO+1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioSetPWMrange(PI_MIN_GPIO-1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioSetPWMrange(GPIO, 24) == PI_BAD_DUTY_RANGE) expect++;
if (gpioSetPWMrange(GPIO, 40001) == PI_BAD_DUTY_RANGE) expect++;
expectExpected(4);
if (gpioGetPWMrange(PI_MAX_USER_GPIO+1) == PI_BAD_USER_GPIO) expect++;
if (gpioGetPWMrange(PI_MIN_GPIO-1) == PI_BAD_USER_GPIO) expect++;
expectExpected(2);
if (gpioGetPWMrealRange(PI_MAX_USER_GPIO+1) == PI_BAD_USER_GPIO) expect++;
if (gpioGetPWMrealRange(PI_MIN_GPIO-1) == PI_BAD_USER_GPIO) expect++;
expectExpected(2);
if (gpioSetPWMfrequency(PI_MAX_USER_GPIO+1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioSetPWMfrequency(PI_MIN_GPIO-1, 0) == PI_BAD_USER_GPIO) expect++;
expectExpected(2);
if (gpioGetPWMfrequency(PI_MAX_USER_GPIO+1) == PI_BAD_USER_GPIO) expect++;
if (gpioGetPWMfrequency(PI_MIN_GPIO-1) == PI_BAD_USER_GPIO) expect++;
expectExpected(2);
if (gpioServo(PI_MAX_USER_GPIO+1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioServo(PI_MIN_GPIO-1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioServo(GPIO, 1) == PI_BAD_PULSEWIDTH) expect++;
if (gpioServo(GPIO,-1) == PI_BAD_PULSEWIDTH) expect++;
if (gpioServo(GPIO, 499) == PI_BAD_PULSEWIDTH) expect++;
if (gpioServo(GPIO, 2501) == PI_BAD_PULSEWIDTH) expect++;
expectExpected(6);
if (gpioSetAlertFunc(PI_MAX_USER_GPIO+1, alert) == PI_BAD_USER_GPIO) expect++;
if (gpioSetAlertFunc(PI_MIN_GPIO-1, alert) == PI_BAD_USER_GPIO) expect++;
expectExpected(2);
if (gpioSetAlertFuncEx(PI_MAX_USER_GPIO+1, alertEx, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioSetAlertFuncEx(PI_MIN_GPIO-1, alertEx, 0) == PI_BAD_USER_GPIO) expect++;
expectExpected(2);
if (gpioSetWatchdog(PI_MAX_USER_GPIO+1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioSetWatchdog(PI_MIN_GPIO-1, 0) == PI_BAD_USER_GPIO) expect++;
if (gpioSetWatchdog(GPIO, 60001) == PI_BAD_WDOG_TIMEOUT) expect++;
if (gpioSetWatchdog(GPIO, -1) == PI_BAD_WDOG_TIMEOUT) expect++;
if (gpioSetWatchdog(GPIO, 0) == 0) expect++;
expectExpected(5);
if (gpioSetTimerFunc(10, 20, tick) == PI_BAD_TIMER) expect++;
if (gpioSetTimerFunc(-1, 20, tick) == PI_BAD_TIMER) expect++;
if (gpioSetTimerFunc(0, 9, tick) == PI_BAD_MS) expect++;
if (gpioSetTimerFunc(0, 60001, tick) == PI_BAD_MS) expect++;
expectExpected(4);
if (gpioSetTimerFuncEx(10, 20, tickEx, 0) == PI_BAD_TIMER) expect++;
if (gpioSetTimerFuncEx(-1, 20, tickEx, 0) == PI_BAD_TIMER) expect++;
if (gpioSetTimerFuncEx(0, 9, tickEx, 0) == PI_BAD_MS) expect++;
if (gpioSetTimerFuncEx(0, 60001, tickEx, 0) == PI_BAD_MS) expect++;
expectExpected(4);
if (gpioTime(-1, &secs, &micros) == PI_BAD_TIMETYPE) expect++;
if (gpioTime(2, &secs, &micros) == PI_BAD_TIMETYPE) expect++;
expectExpected(2);
if (gpioSleep(-1, 1, 0) == PI_BAD_TIMETYPE) expect++;
if (gpioSleep(2, 1, 0) == PI_BAD_TIMETYPE) expect++;
if (gpioSleep(PI_TIME_ABSOLUTE, -1, 0) == PI_BAD_SECONDS) expect++;
if (gpioSleep(PI_TIME_ABSOLUTE, 0, -1) == PI_BAD_MICROS) expect++;
if (gpioSleep(PI_TIME_ABSOLUTE, 0, 1000000) == PI_BAD_MICROS) expect++;
if (gpioSleep(PI_TIME_RELATIVE, -1, 0) == PI_BAD_SECONDS) expect++;
if (gpioSleep(PI_TIME_RELATIVE, 0, -1) == PI_BAD_MICROS) expect++;
if (gpioSleep(PI_TIME_RELATIVE, 0, 1000000) == PI_BAD_MICROS) expect++;
expectExpected(8);
}
void checkGpioTime(void)
{
struct timeval nowA, nowR, tvR, tvA, diffR, diffA;
int diffMicrosA, diffMicrosR;
int i, ok;
int secR, micR, secA, micA;
printf("Library timer tests.\n");
ok = 0;
for (i=0; i<10; i++)
{
gettimeofday(&nowA, NULL); /* reference absolute time */
gpioTime(PI_TIME_ABSOLUTE, &secA, &micA); /* absolute library time */
gpioTime(PI_TIME_RELATIVE, &secR, &micR); /* relative library time */
timersub(&nowA, &libInitTime, &nowR); /* reference relative time */
tvA.tv_sec = secA; tvA.tv_usec = micA;
tvR.tv_sec = secR; tvR.tv_usec = micR;
/* difference between reference and library absolute time */
timersub(&tvA, &nowA, &diffA);
/* difference between reference and library relative time */
timersub(&tvR, &nowR, &diffR);
diffMicrosA = (diffA.tv_sec*1000000)+diffA.tv_usec;
diffMicrosR = (diffR.tv_sec*1000000)+diffR.tv_usec;
if (diffMicrosA < 0) diffMicrosA = -diffMicrosA;
if (diffMicrosR < 0) diffMicrosR = -diffMicrosR;
if ((diffMicrosA < 10) && (diffMicrosR < 500)) ok++;
printf("ABS time diff=%d, REL time diff=%d\n",
diffMicrosA, diffMicrosR);
}
if (ok == 10)
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else printf("TEST %d: FAILED\n\n", test);
++test;
}
void checkGpioSleep(unsigned timetype)
{
struct timeval t1, t2, tD;
int i, ok, secs, micros, diffMicros, expMicros, errMicros;
if (timetype == PI_TIME_ABSOLUTE)
printf("Library gpioSleep ABSOLUTE tests.\n");
else
printf("Library gpioSleep RELATIVE tests.\n");
ok = 0;
for (i=15; i>0; i--)
{
expMicros = i * 100000;
if (timetype == PI_TIME_ABSOLUTE)
{
gpioTime(PI_TIME_ABSOLUTE, &secs, &micros);
secs += (i / 10);
micros += (i % 10) * 100000;
if (micros > 999999) { secs++; micros -= 1000000; }
}
else
{
secs = (i / 10);
micros = (i % 10) * 100000;
}
gettimeofday(&t1, NULL);
gpioSleep(timetype, secs, micros);
gettimeofday(&t2, NULL);
timersub(&t2, &t1, &tD);
diffMicros = (tD.tv_sec*1000000)+tD.tv_usec;
errMicros = diffMicros - expMicros;
if (errMicros < 500) ok++;
printf("secs=%d micros=%d err=%d\n", secs, micros, errMicros);
}
if (ok == 15)
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else printf("TEST %d: FAILED\n\n", test);
++test;
}
int countBank2PinChanges(int pin, int loops)
{
static uint32_t old=0;
uint32_t new, changes;
int i, count;
count = 0;
for (i=0;i<loops;i++)
{
new = gpioRead_Bits_32_53();
changes = new ^ old;
if (changes & (1<<(pin-32))) count++;
}
return count;
}
void checkReadWriteBits(void)
{
uint32_t bank1, bank2;
int i, ok, count1, count2;
printf("Library gpioRead/Write_Bits_x_x_Set/Clear Tests\n");
printf("Expect 0 for pin 47 and >200000 for pin 48.\n");
printf("Expect the green LED to flash.\n\n");
ok = 0;
for (i=0; i<20; i++)
{
gpioWrite_Bits_0_31_Set(1<<GREENLED);
count1 = countBank2PinChanges(SDDET, 1000000);
gpioWrite_Bits_0_31_Clear(1<<GREENLED);
count2 = countBank2PinChanges(SDCLK, 1000000);
bank1 = gpioRead_Bits_0_31();
bank2 = gpioRead_Bits_32_53();
printf("bank1=%08X, bank2=%08X, 47=%d 48=%d\n",
bank1, bank2, count1, count2);
if ((count1 == 0) && (count2 > 200000)) ok++;
}
if (ok == 20)
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else printf("TEST %d: FAILED\n\n", test);
++test;
}
void checkGpioTick(void)
{
uint32_t startTick, endTick;
int diffTick;
printf("Library gpioTick Test\n");
printf("Expect approximately 2 million ticks to have elapsed.\n\n");
startTick = gpioTick();
sleep(2); /* 2 seconds being 2 million ticks */
endTick = gpioTick();
diffTick = endTick - startTick;
printf("%d ticks have elapsed\n", diffTick);
if ((diffTick >= 1990000) && (diffTick <= 2010000))
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
else printf("TEST %d: FAILED\n\n", test);
++test;
}
int main(int argc, char *argv[])
{
int waitfor;
int version, micros=5, millis=100;
if (argc > 1) GPIO = atoi(argv[1]);
fprintf(stderr,
"*****************************************************************\n"\
"* WARNING: This program sends pulses to gpio #%02d *\n"\
"* Make sure that nothing which could be damaged is *\n"\
"* connected to this gpio. A LED or similar should be OK *\n"\
"* although nothing needs to be connected. *\n"\
"* *\n"\
"* NOTE: many of the tests are statistical in nature, assuming *\n"\
"* that events of a short nature will on average be detected *\n"\
"* by sampling. Don't fret if a particular test fails, try *\n"\
"* running the tests again. *\n"\
"* *\n"\
"* You may choose another gpio by specifying its number on *\n"\
"* the command line, e.g. sudo ./checklib 17 will use gpio 17. *\n"\
"* *\n"\
"* Press y (RETURN) to continue, any other character to cancel. *\n"\
"*****************************************************************\n", GPIO);
if (getchar() != 'y') return 0;
printf("Initialisation test\n");
if (argc > 2) micros = atoi(argv[2]);
if (argc > 3) millis = atoi(argv[3]);
gpioCfgBufferSize(millis);
gpioCfgClock(micros, PI_CLOCK_PCM, PI_CLOCK_PLLD);
gettimeofday(&libInitTime, NULL);
version = gpioInitialise();
if (version<0)
{
printf("TEST %d: FAILED\nFATAL ERROR\n", test);
return 1;
}
else
{
printf("TEST %d: PASS, pigpio version is %d\n\n", test, version);
++passes;
}
++test;
waitfor = 2;
printf("Alert function test, wait %d seconds\n", waitfor);
printf("No detected events on gpio 4 expected\n");
inited = 0;
gpioSetAlertFunc(GPIO, alert);
sleep(waitfor);
gpioSetAlertFunc(GPIO, NULL);
printf("Events=%d\n", count);
if (count) printf("TEST %d: FAILED\n\n", test);
else
{
printf("TEST %d: PASS\n\n", test);
++passes;
}
++test;
servoTest(10, 500);
servoTest(10, 1500);
servoTest(10, 2500);
pwmTest(5, 50);
pwmTest(5, 100);
pwmTest(5, 150);
pwmTest(5, 200);
timerTest(5, 100);
timerTest(5, 250);
timerTest(5, 333);
timerTest(5, 1000);
checkValidation();
checkGpioTime();
checkGpioSleep(PI_TIME_RELATIVE);
checkGpioSleep(PI_TIME_ABSOLUTE);
checkReadWriteBits();
checkGpioTick();
printf("Hardware revision is %d\n\n", gpioHardwareRevision());
printf("Summary: %d tests, %d passes\n", test-1, passes);
gpioTerminate(); /* stop DMA and free memory */
return (passes - (test-1));
}