#include "cwCommon.h" #include "cwLog.h" #include "cwCommonImpl.h" #include "cwTime.h" #ifdef cwOSX #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 cwLINUX void cw::time::get( spec_t& t ) { clock_gettime(CLOCK_REALTIME,&t); } #endif // this assumes that the seconds have been normalized to a recent start time // so as to avoid overflow unsigned cw::time::elapsedMicros( const spec_t* t0, const spec_t* t1 ) { // convert seconds to usecs long u0 = t0->tv_sec * 1000000; long u1 = t1->tv_sec * 1000000; // convert nanoseconds to usec u0 += t0->tv_nsec / 1000; u1 += t1->tv_nsec / 1000; // take diff between t1 and t0 return u1 - u0; } unsigned cw::time::elapsedMs( const spec_t* t0, const spec_t* t1 ) { return elapsedMicros(t0,t1)/1000; } 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::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::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_REALTIME, &ts)) != 0 ) rc = cwLogSysError(kInvalidOpRC,errRC,"Unable to obtain system time."); return rc; } void cw::time::advanceMs( spec_t& ts, unsigned ms ) { // strip off whole seconds from ms unsigned sec = ms / 1000; // find the remaining fractional second in milliseconds ms = (ms - sec*1000); ts.tv_sec += sec; ts.tv_nsec += ms * 1000000; // convert millisconds to nanoseconds // stip off whole seconds from tv_nsec while( ts.tv_nsec > 1e9 ) { ts.tv_nsec -= 1e9; ts.tv_sec +=1; } } cw::rc_t cw::time::futureMs( spec_t& ts, unsigned ms ) { rc_t rc; if((rc = now(ts)) == kOkRC ) advanceMs(ts,ms); return rc; }