#include "cwCommon.h" #include "cwLog.h" #include "cwCommonImpl.h" #include "cwTest.h" #include "cwTime.h" #ifdef OS_OSX #include #include #include void cw::time::get( spec_t& t ) { static uint64_t t0 = 0; static mach_timebase_info_data_t tbi; static struct timespec ts; if( t0 == 0 ) { mach_timebase_info(&tbi); t0 = mach_absolute_time(); ts.tv_sec = time(NULL); ts.tv_nsec = 0; // accept 1/2 second error vs. wall-time. } // get the current time uint64_t t1 = mach_absolute_time(); // calc the elapsed time since the last call in nanosecs uint64_t dt = (t1-t0) * tbi.numer / tbi.denom; // calc the elapsed time since the first call in secs uint32_t s = (uint32_t)(dt / 2^9); // calc the current time in secs, and nanosecs t.tv_sec = ts.tv_sec + s; t.tv_nsec = dt - (s * 2^9); } #endif #ifdef OS_LINUX #include // gettimeofday() void cw::time::get( spec_t& t ) { clock_gettime(CLOCK_MONOTONIC,&t); } cw::time::spec_t cw::time::current_time() { spec_t t; get(t); return t; } #endif unsigned long long cw::time::elapsedMicros( const spec_t& t0, const spec_t& t1 ) { const unsigned long long ns_per_sec = 1000000000; const unsigned long long us_per_sec = 1000000; const unsigned long long ns_per_us = 1000; // we assume that the time is normalized assert( t0.tv_nsec < (long long)ns_per_sec ); assert( t1.tv_nsec < (long long)ns_per_sec ); if( t0.tv_sec > t1.tv_sec ) { cwLogWarning("Negative elapsed time detected."); spec_t tt0 = t1; spec_t tt1 = t0; return elapsedMicros(tt0,tt1); } // t1 does not cross a 'seconds' boundary with t0 if( t0.tv_sec == t1.tv_sec ) { // then t0 nsecs must be <= t1 nsecs assert( t0.tv_nsec <= t1.tv_nsec ); return (t1.tv_nsec - t0.tv_nsec)/ns_per_us; } // t1 occurs in a different second than t0 unsigned long long d_sec = (t1.tv_sec - t0.tv_sec) - 1; // difference in seconds unsigned long long d_nsec0 = ns_per_sec - t0.tv_nsec; // time from t0 to next seconds boundary unsigned long long d_nsec1 = t1.tv_nsec; // time from t1 to prev. seconds boundary return (d_sec*us_per_sec) + ((d_nsec0 + d_nsec1)/ns_per_us); } /* unsigned long long cw::time::elapsedMicros0( const spec_t& t0, const spec_t& t1 ) { const unsigned long long us_per_sec = 1000000; const unsigned long long ns_per_us = 1000; // convert seconds to usecs unsigned long long u0 = t0.tv_sec * us_per_sec; unsigned long long u1 = t1.tv_sec * us_per_sec; // convert nanoseconds to usec u0 += t0.tv_nsec / ns_per_us; u1 += t1.tv_nsec / ns_per_us; // take diff between t1 and t0 return u1 - u0; } */ unsigned long long cw::time::elapsedMicros( const spec_t& t0 ) { spec_t t1; get(t1); return elapsedMicros(t0,t1); } unsigned cw::time::elapsedMs( const spec_t& t0, const spec_t& t1 ) { return (unsigned)(elapsedMicros(t0,t1)/1000); } unsigned cw::time::elapsedMs( const spec_t& t0 ) { spec_t t1; get(t1); return elapsedMs(t0,t1); } double cw::time::elapsedSecs( const spec_t& t0, const spec_t& t1 ) { return elapsedMicros(t0,t1) / 1000000.0; } double cw::time::elapsedSecs( const spec_t& t0 ) { spec_t t1; get(t1); return elapsedSecs(t0,t1); } unsigned cw::time::absElapsedMicros( const spec_t& t0, const spec_t& t1 ) { if( isLTE(t0,t1) ) return elapsedMicros(t0,t1); return elapsedMicros(t1,t0); } int cw::time::diffMicros( const spec_t& t0, const spec_t& t1 ) { if( isLTE(t0,t1) ) return elapsedMicros(t0,t1); return -((int)elapsedMicros(t1,t0)); } bool cw::time::isLTE( const spec_t& t0, const spec_t& t1 ) { if( t0.tv_sec < t1.tv_sec ) return true; if( t0.tv_sec == t1.tv_sec ) return t0.tv_nsec <= t1.tv_nsec; return false; } bool cw::time::isLT( const spec_t& t0, const spec_t& t1 ) { if( t0.tv_sec < t1.tv_sec ) return true; if( t0.tv_sec == t1.tv_sec ) return t0.tv_nsec < t1.tv_nsec; return false; } bool cw::time::isGTE( const spec_t& t0, const spec_t& t1 ) { if( t0.tv_sec > t1.tv_sec ) return true; if( t0.tv_sec == t1.tv_sec ) return t0.tv_nsec >= t1.tv_nsec; return false; } bool cw::time::isGT( const spec_t& t0, const spec_t& t1 ) { if( t0.tv_sec > t1.tv_sec ) return true; if( t0.tv_sec == t1.tv_sec ) return t0.tv_nsec > t1.tv_nsec; return false; } bool cw::time::isEqual( const spec_t& t0, const spec_t& t1 ) { return t0.tv_sec==t1.tv_sec && t0.tv_nsec==t1.tv_nsec; } bool cw::time::isZero( const spec_t& t0 ) { return t0.tv_sec==0 && t0.tv_nsec==0; } void cw::time::setZero( spec_t& t0 ) { t0.tv_sec = 0; t0.tv_nsec = 0; } cw::rc_t cw::time::now( spec_t& ts ) { rc_t rc = kOkRC; int errRC; memset(&ts,0,sizeof(ts)); if((errRC = clock_gettime(CLOCK_MONOTONIC, &ts)) != 0 ) rc = cwLogSysError(kInvalidOpRC,errRC,"Unable to obtain system time."); return rc; } void cw::time::subtractMicros( spec_t& ts, unsigned micros ) { unsigned rem_us = micros % 1000000; // fractional seconds in microseconds unsigned rem_ns = rem_us * 1000; // fractional seconds in nanoseconds // if the fractional micros is greater than the fractional nano's if( rem_ns > ts.tv_nsec ) { // subtract the fractional nano's from the fractional micros // (this sets the fractional nano's to 0) rem_ns -= ts.tv_nsec; // convert the remaining fractional micros to the fractional nano's ts.tv_nsec = 1000000000 - rem_ns; // subtract the carry ts.tv_sec -= 1; } else { ts.tv_nsec -= rem_ns; } assert( ts.tv_sec > micros / 1000000 ); ts.tv_sec -= micros / 1000000; } void cw::time::advanceMicros( spec_t& ts, unsigned us ) { const unsigned ns_per_sec = 1000000000; ts.tv_nsec += us * 1000; // convert us to nano's // check if nano's now have more than ns_pser_sec time_t sec = ts.tv_nsec / ns_per_sec; ts.tv_sec += sec; ts.tv_nsec -= sec * ns_per_sec; } void cw::time::advanceMs( spec_t& ts, unsigned ms ) { const unsigned ns_per_sec = 1000000000; ts.tv_nsec += ms * 1000000; time_t sec = ts.tv_nsec / ns_per_sec; ts.tv_sec += sec; ts.tv_nsec -= sec * ns_per_sec; } cw::rc_t cw::time::futureMs( spec_t& ts, unsigned ms ) { rc_t rc; if((rc = now(ts)) == kOkRC ) advanceMs(ts,ms); return rc; } void cw::time::fracSecondsToSpec( spec_t& ts, double sec ) { const unsigned long long ns_per_sec = 1000000000; ts.tv_sec = (unsigned long long)sec; ts.tv_nsec = (sec - ts.tv_sec) * ns_per_sec; } void cw::time::secondsToSpec( spec_t& ts, unsigned sec ) { ts.tv_sec = sec; ts.tv_nsec = 0; } double cw::time::specToSeconds( const spec_t& t ) { const long long ns_per_sec = 1000000000; spec_t ts = t; double sec = ts.tv_sec; while( ts.tv_nsec >= ns_per_sec ) { sec += 1.0; ts.tv_nsec -= ns_per_sec; } return sec + ((double)ts.tv_nsec)/1e9; } unsigned long long cw::time::specToMicroseconds( const spec_t& ts ) { const unsigned long long us_per_sec = 1000000; const unsigned long long ns_per_sec = 1000000000; unsigned long long us = ts.tv_sec * us_per_sec; unsigned long long sec = ts.tv_nsec / ns_per_sec; us += sec * us_per_sec; us += (ts.tv_nsec - (sec * ns_per_sec))/1000; return us; } void cw::time::millisecondsToSpec( spec_t& ts, unsigned ms ) { unsigned sec = ms/1000; unsigned ns = (ms - (sec*1000)) * 1000000; ts.tv_sec = sec; ts.tv_nsec = ns; } void cw::time::microsecondsToSpec( spec_t& ts, unsigned long long us ) { const unsigned long long usPerSec = 1000000; unsigned long long sec = us/usPerSec; unsigned long long ns = (us - (sec*usPerSec)) * 1000; ts.tv_sec = sec; ts.tv_nsec = ns; } cw::time::spec_t cw::time::microsecondsToSpec( unsigned long long us ) { spec_t ts; microsecondsToSpec(ts,us); return ts; } unsigned cw::time::formatDateTime( char* buffer, unsigned bufN, bool includeDateFl ) { // from here: https://stackoverflow.com/questions/3673226/how-to-print-time-in-format-2009-08-10-181754-811 int millisec; struct tm* tm_info; struct timeval tv; int n = 0; gettimeofday(&tv, NULL); millisec = lrint(tv.tv_usec/1000.0); // Round to nearest millisec // Allow for rounding up to nearest second if (millisec>=1000) { millisec -=1000; tv.tv_sec++; } tm_info = localtime(&tv.tv_sec); const char* fmt = "%H:%M:%S"; if( includeDateFl ) fmt = "%Y:%m:%d %H:%M:%S"; n = strftime(buffer, bufN, fmt, tm_info); if( n < (int)bufN && bufN-n >= 5 ) n = snprintf(buffer + n, bufN-n,".%03d", millisec); return (unsigned)n; } cw::rc_t cw::time::test(const test::test_args_t& test ) { spec_t t0,t1; get(t0); futureMs(t1,1000); unsigned dMs = elapsedMs(t0,t1); cwLogPrint("dMs:%i : GTE:%i LTE:%i\n",dMs, isGTE(t0,t1), isLTE(t0,t1) ); microsecondsToSpec( t0, 2500000 ); // 2.5 seconds cwLogPrint("%li %li\n",t0.tv_sec,t0.tv_nsec); subtractMicros( t0, 750000 ); // subtract .75 seconds cwLogPrint("%li %li\n",t0.tv_sec,t0.tv_nsec); subtractMicros( t0, 500000 ); // subtract .5 seconds cwLogPrint("%li %li\n",t0.tv_sec,t0.tv_nsec); time::get(t0); //time::get(t1); t1 = t0; advanceMicros(t1,5000); int usec = time::elapsedMicros(t0,t1); cwLogPrint("usec:%i\n",usec); t0 = current_time(); sleepMs(1000); cwLogPrint("sleep %i ms\n",elapsedMs(t0)); cw::time::fracSecondsToSpec( t0, 12.34567 ); double sec = specToSeconds( t0 ); cwLogPrint("fsecs: %f\n",sec); return kOkRC; }