Commit 03b33425 authored by Sergei Golubchik's avatar Sergei Golubchik

many changes to my_getsystime.c:

* my_getsystime() is only an interval timer. Its value can beused for calculating
  time intervals.
* renamed my_getsystime() to my_interval_timer(), to make the semantics
  clearer and let the compiler catch wrong usages of my_getsystime()
  (also future ones, that may come in merges).
* increased its granularity from 100ns to 1ns, old value was for UUID,
  but as UUID can no longer use it directly there is no need to downgrade
  the OS provided value
* fixed the UUID code to anchor the my_interval_timer() on the epoch, as
  required by the UUID standard. That is, this was only needed by UUID,
  and now I've moved it to UUID code from my_getsystime().
* fixed other wrong usages of my_getsystime() - e.g. in calculating
  times for pthread_cond_timedwait. It was buggy and could've caused
  long waits if OS clock would be changed.
parent 8ddcd0cd
...@@ -8516,7 +8516,7 @@ void timer_output(void) ...@@ -8516,7 +8516,7 @@ void timer_output(void)
ulonglong timer_now(void) ulonglong timer_now(void)
{ {
return my_micro_time() / 1000; return my_interval_timer() / 1000000;
} }
......
...@@ -426,9 +426,9 @@ int my_pthread_mutex_trylock(pthread_mutex_t *mutex); ...@@ -426,9 +426,9 @@ int my_pthread_mutex_trylock(pthread_mutex_t *mutex);
#ifndef set_timespec_nsec #ifndef set_timespec_nsec
#define set_timespec_nsec(ABSTIME,NSEC) \ #define set_timespec_nsec(ABSTIME,NSEC) \
{ \ { \
ulonglong now= my_getsystime() + (NSEC/100); \ ulonglong now= my_hrtime().val*1000 + (NSEC); \
(ABSTIME).ts_sec= (now / ULL(10000000)); \ (ABSTIME).ts_sec= now / 1000000000ULL; \
(ABSTIME).ts_nsec= (now % ULL(10000000) * 100 + ((NSEC) % 100)); \ (ABSTIME).ts_nsec= now % 1000000000ULL; \
} }
#endif /* !set_timespec_nsec */ #endif /* !set_timespec_nsec */
#else #else
...@@ -444,9 +444,9 @@ int my_pthread_mutex_trylock(pthread_mutex_t *mutex); ...@@ -444,9 +444,9 @@ int my_pthread_mutex_trylock(pthread_mutex_t *mutex);
#ifndef set_timespec_nsec #ifndef set_timespec_nsec
#define set_timespec_nsec(ABSTIME,NSEC) \ #define set_timespec_nsec(ABSTIME,NSEC) \
{\ {\
ulonglong now= my_getsystime() + (NSEC/100); \ ulonglong now= my_hrtime().val*1000 + (NSEC); \
(ABSTIME).tv_sec= (time_t) (now / ULL(10000000)); \ (ABSTIME).tv_sec= (time_t) (now / 1000000000ULL); \
(ABSTIME).tv_nsec= (long) (now % ULL(10000000) * 100 + ((NSEC) % 100)); \ (ABSTIME).tv_nsec= (long) (now % 1000000000ULL); \
} }
#endif /* !set_timespec_nsec */ #endif /* !set_timespec_nsec */
#endif /* HAVE_TIMESPEC_TS_SEC */ #endif /* HAVE_TIMESPEC_TS_SEC */
......
...@@ -894,21 +894,18 @@ extern ulong crc32(ulong crc, const uchar *buf, uint len); ...@@ -894,21 +894,18 @@ extern ulong crc32(ulong crc, const uchar *buf, uint len);
extern uint my_set_max_open_files(uint files); extern uint my_set_max_open_files(uint files);
void my_free_open_file_info(void); void my_free_open_file_info(void);
#define HRTIME_RESOLUTION 1000000 #define HRTIME_RESOLUTION 1000000 /* microseconds */
typedef struct {ulonglong val;} my_hrtime_t; typedef struct {ulonglong val;} my_hrtime_t;
typedef struct {ulonglong val;} my_timediff_t;
void my_time_init(); void my_time_init();
extern my_hrtime_t my_hrtime(); extern my_hrtime_t my_hrtime();
void my_diff_and_hrtime(my_timediff_t *interval, my_hrtime_t *timestamp); extern ulonglong my_interval_timer(void);
extern ulonglong my_getsystime(void);
#define my_micro_time() (my_getsystime()/10) #define microsecond_interval_timer() (my_interval_timer()/1000)
#define hrtime_to_time(X) ((X).val/1000000) #define hrtime_to_time(X) ((X).val/1000000)
#define hrtime_from_time(X) ((ulonglong)((X)*1000000ULL)) #define hrtime_from_time(X) ((ulonglong)((X)*1000000ULL))
#define hrtime_to_double(X) ((X).val/(double)HRTIME_RESOLUTION) #define hrtime_to_double(X) ((X).val/(double)HRTIME_RESOLUTION)
#define hrtime_sec_part(X) ((ulong)((X).val%1000000)) #define hrtime_sec_part(X) ((ulong)((X).val%1000000))
#define my_time(X) hrtime_to_time(my_hrtime()) #define my_time(X) hrtime_to_time(my_hrtime())
#define my_micro_and_hrtime(X,Y) my_diff_and_hrtime(X,Y)
extern my_bool my_gethwaddr(uchar *to); extern my_bool my_gethwaddr(uchar *to);
extern int my_getncpus(); extern int my_getncpus();
......
...@@ -14,67 +14,66 @@ ...@@ -14,67 +14,66 @@
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
/*
TODO: in functions my_micro_time() and my_micro_time_and_time() there
exists some common code that should be merged into a function.
*/
#include "mysys_priv.h" #include "mysys_priv.h"
#include "my_static.h" #include "my_static.h"
#ifdef __NETWARE__ #ifdef __NETWARE__
#include <nks/time.h> #include <nks/time.h>
#elif defined(__WIN__) #elif defined(__WIN__)
static ulonglong query_performance_frequency, query_performance_offset;
#define OFFSET_TO_EPOC 116444736000000000LL #define OFFSET_TO_EPOC 116444736000000000LL
#elif defined(HAVE_GETHRTIME) static ulonglong query_performance_frequency;
static ulonglong gethrtime_offset;
#endif #endif
/* /*
get time since epoc in 100 nanosec units return number of nanoseconds since unspecified (but always the same)
point in the past
NOTE: NOTE:
Thus to get the current time we should use the system function Thus to get the current time we should use the system function
with the highest possible resolution with the highest possible resolution
The value is not subject to resetting or drifting by way of adjtime() or The value is not not anchored to any specific point in time (e.g. epoch) nor
settimeofday(), and thus it is *NOT* appropriate for getting the current is it subject to resetting or drifting by way of adjtime() or settimeofday(),
timestamp. It can be used for calculating time intervals, though. and thus it is *NOT* appropriate for getting the current timestamp. It can be
And it's good enough for UUID. used for calculating time intervals, though.
*/ */
ulonglong my_getsystime() ulonglong my_interval_timer()
{ {
#ifdef HAVE_CLOCK_GETTIME #ifdef HAVE_CLOCK_GETTIME
struct timespec tp; struct timespec tp;
clock_gettime(CLOCK_REALTIME, &tp); clock_gettime(CLOCK_MONOTONIC, &tp);
return (ulonglong)tp.tv_sec*10000000+(ulonglong)tp.tv_nsec/100; return tp.tv_sec*1000000000ULL+tp.tv_nsec;
#elif defined(HAVE_GETHRTIME) #elif defined(HAVE_GETHRTIME)
return gethrtime()/100-gethrtime_offset; return gethrtime();
#elif defined(__WIN__) #elif defined(__WIN__)
LARGE_INTEGER t_cnt; LARGE_INTEGER t_cnt;
if (query_performance_frequency) if (query_performance_frequency)
{ {
QueryPerformanceCounter(&t_cnt); QueryPerformanceCounter(&t_cnt);
return ((t_cnt.QuadPart / query_performance_frequency * 10000000) + return (t_cnt.QuadPart / query_performance_frequency * 1000000000ULL) +
((t_cnt.QuadPart % query_performance_frequency) * 10000000 / ((t_cnt.QuadPart % query_performance_frequency) * 1000000000ULL /
query_performance_frequency) + query_performance_offset); query_performance_frequency);
}
else
{
ulonglong newtime;
GetSystemTimeAsFileTime((FILETIME*)&newtime);
return newtime*100ULL;
} }
return 0;
#elif defined(__NETWARE__) #elif defined(__NETWARE__)
NXTime_t tm; NXTime_t tm;
NXGetTime(NX_SINCE_1970, NX_NSECONDS, &tm); NXGetTime(NX_SINCE_1970, NX_NSECONDS, &tm);
return (ulonglong)tm/100; return (ulonglong)tm;
#else #else
/* TODO: check for other possibilities for hi-res timestamping */ /* TODO: check for other possibilities for hi-res timestamping */
struct timeval tv; struct timeval tv;
gettimeofday(&tv,NULL); gettimeofday(&tv,NULL);
return (ulonglong)tv.tv_sec*10000000+(ulonglong)tv.tv_usec*10; return tv.tv_sec*1000000000ULL+tv.tv_usec*1000ULL;
#endif #endif
} }
/* Return current time in microseconds since epoch */ /* Return current time in HRTIME_RESOLUTION (microseconds) since epoch */
my_hrtime_t my_hrtime() my_hrtime_t my_hrtime()
{ {
...@@ -84,60 +83,24 @@ my_hrtime_t my_hrtime() ...@@ -84,60 +83,24 @@ my_hrtime_t my_hrtime()
GetSystemTimeAsFileTime((FILETIME*)&newtime); GetSystemTimeAsFileTime((FILETIME*)&newtime);
newtime -= OFFSET_TO_EPOC; newtime -= OFFSET_TO_EPOC;
hrtime.val= newtime/10; hrtime.val= newtime/10;
#elif defined(HAVE_GETHRTIME) #elif defined(HAVE_CLOCK_GETTIME)
struct timeval t; struct timespec tp;
/* clock_gettime(CLOCK_REALTIME, &tp);
The following loop is here because gettimeofday may fail on some systems return tp.tv_sec*1000000ULL+tp.tv_nsec/1000ULL;
*/
while (gettimeofday(&t, NULL) != 0)
{}
hrtime.val= t.tv_sec*1000000 + t.tv_usec;
#else #else
hrtime.val= my_getsystime()/10; struct timeval t;
/* The following loop is here because gettimeofday may fail on some systems */
while (gettimeofday(&t, NULL) != 0) {}
hrtime.val= t.tv_sec*1000000ULL + t.tv_usec;
#endif #endif
return hrtime; return hrtime;
} }
/*
This function is basically equivalent to
*interval= my_getsystime()/10;
*timestamp= my_time();
but it avoids calling OS time functions twice, if possible.
*/
void my_diff_and_hrtime(my_timediff_t *interval, my_hrtime_t *timestamp)
{
interval->val= my_getsystime() / 10;
#if defined(__WIN__) || defined(HAVE_GETHRTIME)
*timestamp= my_hrtime();
#else
timestamp->val= interval->val;
#endif
}
void my_time_init() void my_time_init()
{ {
#ifdef __WIN__ #ifdef __WIN__
FILETIME ft; compile_time_assert(sizeof(LARGE_INTEGER) == sizeof(query_performance_frequency));
LARGE_INTEGER li, t_cnt;
DBUG_ASSERT(sizeof(LARGE_INTEGER) == sizeof(query_performance_frequency));
if (QueryPerformanceFrequency((LARGE_INTEGER *)&query_performance_frequency) == 0) if (QueryPerformanceFrequency((LARGE_INTEGER *)&query_performance_frequency) == 0)
query_performance_frequency= 0; query_performance_frequency= 0;
else
{
GetSystemTimeAsFileTime(&ft);
li.LowPart= ft.dwLowDateTime;
li.HighPart= ft.dwHighDateTime;
query_performance_offset= li.QuadPart-OFFSET_TO_EPOC;
QueryPerformanceCounter(&t_cnt);
query_performance_offset-= (t_cnt.QuadPart /
query_performance_frequency * 10000000 +
t_cnt.QuadPart %
query_performance_frequency * 10000000 /
query_performance_frequency);
}
#elif defined(HAVE_GETHRTIME)
gethrtime_offset= gethrtime();
#endif #endif
} }
...@@ -596,15 +596,15 @@ bool do_test(uint no_parts, uint l_max_ind, bool l_fix_used) ...@@ -596,15 +596,15 @@ bool do_test(uint no_parts, uint l_max_ind, bool l_fix_used)
static void start_measurement() static void start_measurement()
{ {
start_time= my_getsystime(); start_time= my_interval_timer();
} }
static void stop_measurement() static void stop_measurement()
{ {
ulonglong stop_time= my_getsystime(); ulonglong stop_time= my_interval_timer();
uint time_in_micros; uint time_in_micros;
stop_time-= start_time; stop_time-= start_time;
stop_time/= 10; /* Convert to microseconds */ stop_time/= 1000; /* Convert to microseconds */
time_in_micros= (uint)stop_time; time_in_micros= (uint)stop_time;
printf("Time expired is %u microseconds \n", time_in_micros); printf("Time expired is %u microseconds \n", time_in_micros);
} }
......
...@@ -3446,6 +3446,8 @@ String *Item_func_uncompress::val_str(String *str) ...@@ -3446,6 +3446,8 @@ String *Item_func_uncompress::val_str(String *str)
static struct rand_struct uuid_rand; static struct rand_struct uuid_rand;
static uint nanoseq; static uint nanoseq;
static ulonglong uuid_time=0; static ulonglong uuid_time=0;
static longlong interval_timer_offset;
static char clock_seq_and_node_str[]="-0000-000000000000"; static char clock_seq_and_node_str[]="-0000-000000000000";
/** /**
...@@ -3473,6 +3475,7 @@ static void set_clock_seq_str() ...@@ -3473,6 +3475,7 @@ static void set_clock_seq_str()
uint16 clock_seq= ((uint)(my_rnd(&uuid_rand)*16383)) | UUID_VARIANT; uint16 clock_seq= ((uint)(my_rnd(&uuid_rand)*16383)) | UUID_VARIANT;
tohex(clock_seq_and_node_str+1, clock_seq, 4); tohex(clock_seq_and_node_str+1, clock_seq, 4);
nanoseq= 0; nanoseq= 0;
interval_timer_offset= my_hrtime().val * 10 - my_interval_timer()/100 + UUID_TIME_OFFSET;
} }
String *Item_func_uuid::val_str(String *str) String *Item_func_uuid::val_str(String *str)
...@@ -3512,7 +3515,7 @@ String *Item_func_uuid::val_str(String *str) ...@@ -3512,7 +3515,7 @@ String *Item_func_uuid::val_str(String *str)
set_clock_seq_str(); set_clock_seq_str();
} }
ulonglong tv= my_getsystime() + UUID_TIME_OFFSET + nanoseq; ulonglong tv= my_interval_timer()/100 + interval_timer_offset + nanoseq;
if (likely(tv > uuid_time)) if (likely(tv > uuid_time))
{ {
...@@ -3564,7 +3567,7 @@ String *Item_func_uuid::val_str(String *str) ...@@ -3564,7 +3567,7 @@ String *Item_func_uuid::val_str(String *str)
irrelevant in the new numberspace. irrelevant in the new numberspace.
*/ */
set_clock_seq_str(); set_clock_seq_str();
tv= my_getsystime() + UUID_TIME_OFFSET; tv= my_interval_timer()/100 + interval_timer_offset;
nanoseq= 0; nanoseq= 0;
DBUG_PRINT("uuid",("making new numberspace")); DBUG_PRINT("uuid",("making new numberspace"));
} }
......
...@@ -1947,7 +1947,7 @@ static bool cache_thread() ...@@ -1947,7 +1947,7 @@ static bool cache_thread()
this thread for handling of new THD object/connection. this thread for handling of new THD object/connection.
*/ */
thd->mysys_var->abort= 0; thd->mysys_var->abort= 0;
thd->thr_create_utime= my_micro_time(); thd->thr_create_utime= microsecond_interval_timer();
threads.append(thd); threads.append(thd);
return(1); return(1);
} }
...@@ -4907,7 +4907,7 @@ void handle_connection_in_main_thread(THD *thd) ...@@ -4907,7 +4907,7 @@ void handle_connection_in_main_thread(THD *thd)
thread_cache_size=0; // Safety thread_cache_size=0; // Safety
threads.append(thd); threads.append(thd);
pthread_mutex_unlock(&LOCK_thread_count); pthread_mutex_unlock(&LOCK_thread_count);
thd->start_utime= my_micro_time(); thd->start_utime= microsecond_interval_timer();
handle_one_connection(thd); handle_one_connection(thd);
} }
...@@ -4933,7 +4933,7 @@ void create_thread_to_handle_connection(THD *thd) ...@@ -4933,7 +4933,7 @@ void create_thread_to_handle_connection(THD *thd)
thread_created++; thread_created++;
threads.append(thd); threads.append(thd);
DBUG_PRINT("info",(("creating thread %lu"), thd->thread_id)); DBUG_PRINT("info",(("creating thread %lu"), thd->thread_id));
thd->prior_thr_create_utime= thd->start_utime= my_micro_time(); thd->prior_thr_create_utime= thd->start_utime= microsecond_interval_timer();
if ((error=pthread_create(&thd->real_id,&connection_attrib, if ((error=pthread_create(&thd->real_id,&connection_attrib,
handle_one_connection, handle_one_connection,
(void*) thd))) (void*) thd)))
......
...@@ -2028,17 +2028,14 @@ class THD :public Statement, ...@@ -2028,17 +2028,14 @@ class THD :public Statement,
{ {
start_time= hrtime_to_my_time(user_time); start_time= hrtime_to_my_time(user_time);
start_time_sec_part= hrtime_sec_part(user_time); start_time_sec_part= hrtime_sec_part(user_time);
start_utime= utime_after_lock= my_micro_time();
} }
else else
{ {
my_hrtime_t hrtime; my_hrtime_t hrtime= my_hrtime();
my_timediff_t timediff;
my_micro_and_hrtime(&timediff, &hrtime);
start_time= hrtime_to_my_time(hrtime); start_time= hrtime_to_my_time(hrtime);
start_time_sec_part= hrtime_sec_part(hrtime); start_time_sec_part= hrtime_sec_part(hrtime);
utime_after_lock= start_utime= timediff.val;
} }
start_utime= utime_after_lock= microsecond_interval_timer();
} }
inline void set_current_time() inline void set_current_time()
{ {
...@@ -2051,15 +2048,15 @@ class THD :public Statement, ...@@ -2051,15 +2048,15 @@ class THD :public Statement,
user_time= t; user_time= t;
start_time= hrtime_to_my_time(user_time); start_time= hrtime_to_my_time(user_time);
start_time_sec_part= hrtime_sec_part(user_time); start_time_sec_part= hrtime_sec_part(user_time);
start_utime= utime_after_lock= my_micro_time(); start_utime= utime_after_lock= microsecond_interval_timer();
} }
inline void set_time(my_time_t t, ulong sec_part) inline void set_time(my_time_t t, ulong sec_part)
{ {
my_hrtime_t hrtime= { hrtime_from_time(t) + sec_part }; my_hrtime_t hrtime= { hrtime_from_time(t) + sec_part };
set_time(hrtime); set_time(hrtime);
} }
void set_time_after_lock() { utime_after_lock= my_micro_time(); } void set_time_after_lock() { utime_after_lock= microsecond_interval_timer(); }
ulonglong current_utime() { return my_micro_time(); } ulonglong current_utime() { return microsecond_interval_timer(); }
inline ulonglong found_rows(void) inline ulonglong found_rows(void)
{ {
return limit_found_rows; return limit_found_rows;
......
...@@ -1084,7 +1084,7 @@ pthread_handler_t handle_one_connection(void *arg) ...@@ -1084,7 +1084,7 @@ pthread_handler_t handle_one_connection(void *arg)
{ {
THD *thd= (THD*) arg; THD *thd= (THD*) arg;
thd->thr_create_utime= my_micro_time(); thd->thr_create_utime= microsecond_interval_timer();
if (thread_scheduler.init_new_connection_thread()) if (thread_scheduler.init_new_connection_thread())
{ {
......
...@@ -221,7 +221,7 @@ void PROF_MEASUREMENT::set_label(const char *status_arg, ...@@ -221,7 +221,7 @@ void PROF_MEASUREMENT::set_label(const char *status_arg,
*/ */
void PROF_MEASUREMENT::collect() void PROF_MEASUREMENT::collect()
{ {
time_usecs= (double) my_getsystime() / 10.0; /* 1 sec was 1e7, now is 1e6 */ time_usecs= my_interval_timer() / 1e3; /* ns to us */
#ifdef HAVE_GETRUSAGE #ifdef HAVE_GETRUSAGE
getrusage(RUSAGE_SELF, &rusage); getrusage(RUSAGE_SELF, &rusage);
#endif #endif
......
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