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libcm is a C development framework with an emphasis on audio signal processing applications.
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libcm/cmTime.c

cmTime.c 2.5KB
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  1. #include "cmPrefix.h"

  2. #include "cmGlobal.h"

  3. #include "cmTime.h"

  4. 

  5. #ifdef OS_OSX

  6. 

  7. #include <mach/mach.h>

  8. #include <mach/mach_time.h>

  9. #include <unistd.h>

  10. 

  11. void cmTimeGet( cmTimeSpec_t* t )

  12. {

  13.   static uint64_t                  t0  = 0;

  14.   static mach_timebase_info_data_t tbi;

  15.   static struct timespec           ts;

  16. 

  17.   if( t0 == 0 )

  18.   {

  19.     mach_timebase_info(&tbi);

  20.     t0 = mach_absolute_time();

  21.     ts.tv_sec  = time(NULL);

  22.     ts.tv_nsec = 0;  // accept 1/2 second error vs. wall-time.

  23.   }

  24. 

  25.   // get the current time

  26.   uint64_t t1 = mach_absolute_time();

  27.   

  28.   // calc the elapsed time since the last call in nanosecs

  29.   uint64_t dt = (t1-t0) * tbi.numer / tbi.denom;

  30. 

  31.   // calc the elapsed time since the first call in secs

  32.   uint32_t s  = (uint32_t)(dt / 2^9);

  33. 

  34.   // calc the current time in secs, and nanosecs

  35.   t->tv_sec  = ts.tv_sec + s; 

  36.   t->tv_nsec = dt - (s * 2^9); 

  37.   

  38. }

  39. 

  40. #endif

  41. 

  42. #ifdef OS_LINUX

  43. void cmTimeGet( cmTimeSpec_t* t )

  44. { clock_gettime(CLOCK_REALTIME,t); }

  45. #endif

  46. 

  47. // this assumes that the seconds have been normalized to a recent start time

  48. // so as to avoid overflow

  49. unsigned cmTimeElapsedMicros( const cmTimeSpec_t* t0, const cmTimeSpec_t* t1 )

  50. {

  51.   // convert seconds to usecs

  52.   long u0 = t0->tv_sec * 1000000;

  53.   long u1 = t1->tv_sec * 1000000;

  54. 

  55.   // convert nanoseconds to usec

  56.   u0 += t0->tv_nsec / 1000;

  57.   u1 += t1->tv_nsec / 1000;

  58. 

  59.   // take diff between t1 and t0

  60.   return u1 - u0;

  61. }

  62. 

  63. unsigned cmTimeAbsElapsedMicros( const cmTimeSpec_t*  t0, const cmTimeSpec_t* t1 )

  64. {

  65.   if( cmTimeIsLTE(t0,t1) )

  66.     return cmTimeElapsedMicros(t0,t1);

  67. 

  68.   return cmTimeElapsedMicros(t1,t0);

  69. }

  70. 

  71. int cmTimeDiffMicros( const cmTimeSpec_t*  t0, const cmTimeSpec_t* t1 )

  72. {

  73.   if( cmTimeIsLTE(t0,t1) )

  74.     return cmTimeElapsedMicros(t0,t1);

  75. 

  76.   return -((int)cmTimeElapsedMicros(t1,t0));

  77. }

  78. 

  79. bool cmTimeIsLTE( const cmTimeSpec_t* t0, const cmTimeSpec_t* t1 )

  80. {

  81.   if( t0->tv_sec  < t1->tv_sec )

  82.     return true;

  83. 

  84.   if( t0->tv_sec == t1->tv_sec )

  85.     return t0->tv_nsec <= t1->tv_nsec;

  86. 

  87.   return false; 

  88. }

  89. 

  90. bool cmTimeIsGTE( const cmTimeSpec_t* t0, const cmTimeSpec_t* t1 )

  91. {

  92.   if( t0->tv_sec  > t1->tv_sec )

  93.     return true;

  94. 

  95.   if( t0->tv_sec == t1->tv_sec )

  96.     return t0->tv_nsec >= t1->tv_nsec;

  97. 

  98.   return false;   

  99. }

  100. 

  101. bool cmTimeIsEqual( const cmTimeSpec_t* t0, const cmTimeSpec_t* t1 )

  102. { return t0->tv_sec==t1->tv_sec && t0->tv_nsec==t1->tv_nsec; }

  103. 

  104. bool cmTimeIsZero( const cmTimeSpec_t* t0 )

  105. { return t0->tv_sec==0  && t0->tv_nsec==0; }

  106. 

  107. void cmTimeSetZero( cmTimeSpec_t* t0 )

  108. {

  109.   t0->tv_sec = 0;

  110.   t0->tv_nsec = 0;

  111. }

  112.