/*************************************************************************\ * Copyright (c) 2006 UChicago Argonne LLC, as Operator of Argonne * National Laboratory. * Copyright (c) 2002 The Regents of the University of California, as * Operator of Los Alamos National Laboratory. * EPICS BASE is distributed subject to a Software License Agreement found * in file LICENSE that is included with this distribution. \*************************************************************************/ /* * Authors: Jeff Hill, Marty Kraimer and Andrew Johnson */ #ifdef __SUNPRO_CC using namespace std; #endif #include #include #include #include #include #include #include "epicsTime.h" #include "epicsThread.h" #include "errlog.h" #include "epicsUnitTest.h" #include "testMain.h" using namespace std; /* The functionality of the old invalidFormatTest () and badNanosecTest () * routines is incorporated into epicsTimeTest () below. */ struct l_fp { /* NTP time stamp */ epicsUInt32 l_ui; /* sec past NTP epoch */ epicsUInt32 l_uf; /* fractional seconds */ }; static const unsigned mSecPerSec = 1000u; static const unsigned uSecPerSec = 1000u * mSecPerSec; static const unsigned nSecPerSec = 1000u * uSecPerSec; static const double precisionEPICS = 1.0 / nSecPerSec; MAIN(epicsTimeTest) { const int wasteTime = 100000; const int nTimes = 10; testPlan(15 + nTimes * 18); try { const epicsTimeStamp epochTS = {0, 0}; epicsTime epochET = epochTS; struct gm_tm_nano_sec epicsEpoch = epochET; testOk(epicsEpoch.ansi_tm.tm_sec == 0 && epicsEpoch.ansi_tm.tm_min == 0 && epicsEpoch.ansi_tm.tm_hour == 0 && epicsEpoch.ansi_tm.tm_yday == 0 && epicsEpoch.ansi_tm.tm_year == 90, "epicsTime_gmtime() for EPICS epoch"); } catch ( ... ) { testFail("epicsTime_gmtime() failed"); testAbort("Can't continue, check your OS!"); } { // badNanosecTest static const char * pFormat = "%a %b %d %Y %H:%M:%S.%4f"; try { const epicsTimeStamp badTS = {1, 1000000000}; epicsTime ts(badTS); char buf [32]; ts.strftime(buf, sizeof(buf), pFormat); testFail("nanosecond overflow returned \"%s\"", buf); } catch ( ... ) { testPass("nanosecond overflow throws"); } } { // strftime() output char buf[80]; epicsTime et; const char * pFormat = "%Y-%m-%d %H:%M:%S.%f"; et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "") == 0, "undefined => '%s'", buf); // This is Noon GMT, when all timezones have the same date const epicsTimeStamp tTS = {12*60*60, 98765432}; et = tTS; pFormat = "%Y-%m-%d %S.%09f"; // %H and %M change with timezone et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "1990-01-01 00.098765432") == 0, "'%s' => '%s'", pFormat, buf); pFormat = "%S.%03f"; et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "00.099") == 0, "'%s' => '%s'", pFormat, buf); pFormat = "%S.%04f"; et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "00.0988") == 0, "'%s' => '%s'", pFormat, buf); pFormat = "%S.%05f"; et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "00.09877") == 0, "'%s' => '%s'", pFormat, buf); pFormat = "%S.%05f %S.%05f"; et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "00.09877 00.09877") == 0, "'%s' => '%s'", pFormat, buf); char smbuf[5]; pFormat = "%S.%05f"; et.strftime(smbuf, sizeof(smbuf), pFormat); testOk(strcmp(smbuf, "00.*") == 0, "'%s' => '%s'", pFormat, smbuf); pFormat = "%S.%03f"; (et + 0.9).strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "00.999") == 0, "0.998765 => '%s'", buf); pFormat = "%S.%03f"; (et + 0.901).strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "00.999") == 0, "0.999765 => '%s'", buf); pFormat = "%%S.%%05f"; et.strftime(buf, sizeof(buf), pFormat); testOk(strcmp(buf, "%S.%05f") == 0, "'%s' => '%s'", pFormat, buf); char bigBuf [512]; memset(bigBuf, '\a', sizeof(bigBuf)); bigBuf[ sizeof(bigBuf) - 1] = '\0'; et.strftime(buf, sizeof(buf), bigBuf); testOk(strcmp(buf, "") == 0, "bad format => '%s'", buf); } epicsTime now; try { now = epicsTime::getCurrent(); testPass("default time provider"); } catch ( ... ) { testFail("epicsTime::getCurrent() throws"); testAbort("Can't continue, check your time provider"); } { l_fp ntp = now; epicsTime tsf = ntp; const double diff = fabs(tsf - now); // the difference in the precision of the two time formats static const double precisionNTP = 1.0 / (1.0 + 0xffffffff); testOk1(diff <= precisionEPICS + precisionNTP); } testDiag("Running %d loops", nTimes); const epicsTime begin = epicsTime::getCurrent(); for (int loop = 0; loop < nTimes; ++loop) { for (int i = 0; i < wasteTime; ++i) { now = epicsTime::getCurrent(); } const double diff = now - begin; if (loop == 0) { testDiag ("%d calls to epicsTime::getCurrent() " "averaged %6.3f usec each", wasteTime, diff * 1e6 / wasteTime); } epicsTime copy = now; testOk1(copy == now); testOk1(copy <= now); testOk1(copy >= now); testOk1(now > begin); testOk1(now >= begin); testOk1(begin != now); testOk1(begin < now); testOk1(begin <= now); testOk1(now - now == 0); testOk(fabs((now - begin) - diff) < precisionEPICS * 0.01, "now - begin ~= diff"); testOk1(begin + 0 == begin); testOk1(begin + diff == now); testOk1(now - 0 == now); testOk1(now - diff == begin); epicsTime end = begin; end += diff; testOk(end == now, "(begin += diff) == now"); end = now; end -= diff; testOk(end == begin, "(now -= diff) == begin"); // test struct tm round-trip conversion local_tm_nano_sec ansiDate = begin; epicsTime beginANSI = ansiDate; testOk1(beginANSI + diff == now); // test struct timespec round-trip conversion struct timespec ts = begin; epicsTime beginTS = ts; testOk1(beginTS + diff == now); } return testDone(); }