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SoftEtherVPN/src/Mayaqua/Kernel.c

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2017-10-19 05:48:23 +03:00
// SoftEther VPN Source Code - Developer Edition Master Branch
2014-01-04 17:00:08 +04:00
// Mayaqua Kernel
// Kernel.c
// System service processing routine
#include <GlobalConst.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <wchar.h>
#include <stdarg.h>
#include <time.h>
#include <errno.h>
#include <Mayaqua/Mayaqua.h>
#ifndef TM_YEAR_MAX
#define TM_YEAR_MAX 2106
#endif
#ifndef TM_MON_MAX
#define TM_MON_MAX 1
#endif
#ifndef TM_MDAY_MAX
#define TM_MDAY_MAX 7
#endif
#ifndef TM_HOUR_MAX
#define TM_HOUR_MAX 6
#endif
#ifndef TM_MIN_MAX
#define TM_MIN_MAX 28
#endif
#ifndef TM_SEC_MAX
#define TM_SEC_MAX 14
#endif
#define ADJUST_TM(tm_member, tm_carry, modulus) \
if ((tm_member) < 0){ \
tm_carry -= (1 - ((tm_member)+1) / (modulus)); \
tm_member = (modulus-1) + (((tm_member)+1) % (modulus)); \
} else if ((tm_member) >= (modulus)) { \
tm_carry += (tm_member) / (modulus); \
tm_member = (tm_member) % (modulus); \
}
#define leap(y) (((y) % 4 == 0 && (y) % 100 != 0) || (y) % 400 == 0)
#define nleap(y) (((y) - 1969) / 4 - ((y) - 1901) / 100 + ((y) - 1601) / 400)
#define leapday(m, y) ((m) == 1 && leap (y))
#define monthlen(m, y) (ydays[(m)+1] - ydays[m] + leapday (m, y))
static int ydays[] =
{
0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365
};
static UINT current_num_thread = 0;
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static UINT cached_number_of_cpus = 0;
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static wchar_t *default_locale_str =
L"- - $ : : $ Sun Mon Tue Wed Thu Fri Sat : : : $ (None)";
static LOCALE current_locale;
LOCK *tick_manual_lock = NULL;
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#define MONSPERYEAR 12
#define DAYSPERNYEAR 365
#define DAYSPERLYEAR 366
#define SECSPERMIN 60
#define SECSPERHOUR (60*60)
#define SECSPERDAY (24*60*60)
#define DAYSPERWEEK 7
#define TM_SUNDAY 0
#define TM_MONDAY 1
#define TM_TUESDAY 2
#define TM_WEDNESDAY 3
#define TM_THURSDAY 4
#define TM_FRIDAY 5
#define TM_SATURDAY 6
#define TM_YEAR_BASE 1900
#define EPOCH_YEAR 1970
#define EPOCH_WDAY TM_THURSDAY
#define isleap(y) (((y) % 4) == 0 && (((y) % 100) != 0 || ((y) % 400) == 0))
static const int mon_lengths[2][MONSPERYEAR] = {
{ 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 },
{ 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }
};
static const int year_lengths[2] = {
DAYSPERNYEAR, DAYSPERLYEAR
};
/*
* Taken from FreeBSD src / lib / libc / stdtime / localtime.c 1.43 revision.
* localtime.c 7.78.
* tzfile.h 1.8
* adapted to be replacement gmtime_r.
*/
static void
c_timesub(timep, offset, tmp)
const time_64t * const timep;
const long offset;
struct tm * const tmp;
{
INT64 days;
INT64 rem;
INT64 y;
int yleap;
const int * ip;
days = *timep / SECSPERDAY;
rem = *timep % SECSPERDAY;
rem += (offset);
while (rem < 0) {
rem += SECSPERDAY;
--days;
}
while (rem >= SECSPERDAY) {
rem -= SECSPERDAY;
++days;
}
tmp->tm_hour = (int) (rem / SECSPERHOUR);
rem = rem % SECSPERHOUR;
tmp->tm_min = (int) (rem / SECSPERMIN);
/*
** A positive leap second requires a special
** representation. This uses "... ??:59:60" et seq.
*/
tmp->tm_sec = (int) (rem % SECSPERMIN) ;
tmp->tm_wday = (int) ((EPOCH_WDAY + days) % DAYSPERWEEK);
if (tmp->tm_wday < 0)
tmp->tm_wday += DAYSPERWEEK;
y = EPOCH_YEAR;
#define LEAPS_THRU_END_OF(y) ((y) / 4 - (y) / 100 + (y) / 400)
while (days < 0 || days >= (long) year_lengths[yleap = isleap(y)]) {
INT64 newy;
newy = y + days / DAYSPERNYEAR;
if (days < 0)
--newy;
days -= (newy - y) * DAYSPERNYEAR +
LEAPS_THRU_END_OF(newy - 1) -
LEAPS_THRU_END_OF(y - 1);
y = newy;
}
tmp->tm_year = (int)(y - TM_YEAR_BASE);
tmp->tm_yday = (int) days;
ip = mon_lengths[yleap];
for (tmp->tm_mon = 0; days >= (INT64) ip[tmp->tm_mon]; ++(tmp->tm_mon))
days = days - (INT64) ip[tmp->tm_mon];
tmp->tm_mday = (int) (days + 1);
tmp->tm_isdst = 0;
}
/*
* Re-entrant version of gmtime.
*/
struct tm * c_gmtime_r(const time_64t* timep, struct tm *tm)
{
c_timesub(timep, 0L, tm);
return tm;
}
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// Get the real-time system timer
UINT TickRealtime()
{
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#if defined(OS_WIN32) || defined(CLOCK_REALTIME) || defined(CLOCK_MONOTONIC) || defined(CLOCK_HIGHRES) || defined(UNIX_MACOS)
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return Tick() + 1;
#else
return TickRealtimeManual() + 1;
#endif
}
#ifndef OS_WIN32
static UINT64 last_manual_tick = 0;
static UINT64 manual_tick_add_value = 0;
// For systems which not have clock_gettime (such as MacOS X)
UINT TickRealtimeManual()
{
UINT64 ret;
Lock(tick_manual_lock);
{
ret = TickGetRealtimeTickValue64();
if (last_manual_tick != 0 && (last_manual_tick > ret))
{
manual_tick_add_value += (last_manual_tick - ret);
}
last_manual_tick = ret;
}
Unlock(tick_manual_lock);
return (UINT)(ret + manual_tick_add_value);
}
// Returns a appropriate value from the current time
UINT64 TickGetRealtimeTickValue64()
{
struct timeval tv;
struct timezone tz;
UINT64 ret;
memset(&tv, 0, sizeof(tv));
memset(&tz, 0, sizeof(tz));
gettimeofday(&tv, &tz);
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if (sizeof(tv.tv_sec) != 4)
{
ret = (UINT64)tv.tv_sec * 1000ULL + (UINT64)tv.tv_usec / 1000ULL;
}
else
{
ret = (UINT64)((UINT64)((UINT32)tv.tv_sec)) * 1000ULL + (UINT64)tv.tv_usec / 1000ULL;
}
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return ret;
}
#endif // OS_WIN32
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// Get the number of CPUs
UINT GetNumberOfCpu()
{
UINT ret = 0;
if (cached_number_of_cpus == 0)
{
UINT i = 0;
#ifdef OS_WIN32
i = Win32GetNumberOfCpuInner();
#else // OS_WIN32
i = UnixGetNumberOfCpuInner();
#endif // OS_WIN32
if (i == 0)
{
i = 8;
}
cached_number_of_cpus = i;
}
ret = cached_number_of_cpus;
if (ret == 0)
{
ret = 1;
}
if (ret > 128)
{
ret = 128;
}
return ret;
}
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// Creating a thread list
LIST *NewThreadList()
{
LIST *o = NewList(NULL);
return o;
}
// Add the thread to the thread list
void AddThreadToThreadList(LIST *o, THREAD *t)
{
// Validate arguments
if (o == NULL || t == NULL)
{
return;
}
LockList(o);
{
if (IsInList(o, t) == false)
{
AddRef(t->ref);
Add(o, t);
}
}
UnlockList(o);
}
// Maintain thread list
Correct Spelling (#458) * spelling: accepts * spelling: account * spelling: accept * spelling: accumulate * spelling: adapter * spelling: address * spelling: additional * spelling: aggressive * spelling: adhered * spelling: allowed * spelling: ambiguous * spelling: amount * spelling: anonymous * spelling: acquisition * spelling: assemble * spelling: associated * spelling: assigns * spelling: attach * spelling: attempt * spelling: attribute * spelling: authenticate * spelling: authentication * spelling: available * spelling: bridging * spelling: cascade * spelling: cancel * spelling: check * spelling: challenge * spelling: changing * spelling: characters * spelling: cloud * spelling: compare * spelling: communication * spelling: compatible * spelling: compatibility * spelling: completion * spelling: complete * spelling: computers * spelling: configure * spelling: configuration * spelling: conformant * spelling: connection * spelling: contains * spelling: continuously * spelling: continue * spelling: convert * spelling: counters * spelling: create * spelling: created * spelling: cumulate * spelling: currently * spelling: debugging * spelling: decryption * spelling: description * spelling: default * spelling: driver * spelling: delete * spelling: destination * spelling: disabled * spelling: different * spelling: dynamically * spelling: directory * spelling: disappeared * spelling: disable * spelling: doesn't * spelling: download * spelling: dropped * spelling: enable * spelling: established * spelling: ether * spelling: except * spelling: expired * spelling: field * spelling: following * spelling: forever * spelling: firewall * spelling: first * spelling: fragment * spelling: function * spelling: gateway * spelling: identifier * spelling: identify * spelling: incoming * spelling: information * spelling: initialize * spelling: injection * spelling: inner * spelling: instead * spelling: installation * spelling: inserted * spelling: integer * spelling: interrupt * spelling: intuitive * spelling: interval * spelling: january * spelling: keybytes * spelling: know * spelling: language * spelling: length * spelling: library * spelling: listener * spelling: maintain * spelling: modified * spelling: necessary * spelling: number * spelling: obsoleted * spelling: occurred * spelling: occurring * spelling: occur * spelling: original * spelling: omittable * spelling: omit * spelling: opening * spelling: operation * spelling: packet * spelling: parameters * spelling: pointed * spelling: popupmenuopen * spelling: privilege * spelling: product * spelling: protection * spelling: promiscuous * spelling: prompt * spelling: query * spelling: random * spelling: reconnection * spelling: revocation * spelling: received * spelling: red hat * spelling: registry * spelling: release * spelling: retrieve
2018-05-17 00:47:10 +03:00
void MaintainThreadList(LIST *o)
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{
UINT i;
LIST *delete_list = NULL;
// Validate arguments
if (o == NULL)
{
return;
}
LockList(o);
{
for (i = 0;i < LIST_NUM(o);i++)
{
THREAD *t = LIST_DATA(o, i);
if (t->Stopped)
{
if (delete_list == NULL)
{
delete_list = NewListFast(NULL);
}
Add(delete_list, t);
}
}
if (delete_list != NULL)
{
for (i = 0;i < LIST_NUM(delete_list);i++)
{
THREAD *t = LIST_DATA(delete_list, i);
ReleaseThread(t);
Delete(o, t);
}
ReleaseList(delete_list);
}
}
UnlockList(o);
}
// Stop all the threads in the thread list
void StopThreadList(LIST *o)
{
UINT i;
// Validate arguments
if (o == NULL)
{
return;
}
LockList(o);
{
for (i = 0;i < LIST_NUM(o);i++)
{
THREAD *t = LIST_DATA(o, i);
WaitThread(t, INFINITE);
}
}
UnlockList(o);
}
// Release the thread list
void FreeThreadList(LIST *o)
{
UINT i;
// Validate arguments
if (o == NULL)
{
return;
}
LockList(o);
{
for (i = 0;i < LIST_NUM(o);i++)
{
THREAD *t = LIST_DATA(o, i);
WaitThread(t, INFINITE);
ReleaseThread(t);
}
DeleteAll(o);
}
UnlockList(o);
ReleaseList(o);
}
// Get the home directory
void GetHomeDirW(wchar_t *path, UINT size)
{
// Validate arguments
if (path == NULL)
{
return;
}
if (GetEnvW(L"HOME", path, size) == false)
{
wchar_t drive[MAX_SIZE];
wchar_t hpath[MAX_SIZE];
if (GetEnvW(L"HOMEDRIVE", drive, sizeof(drive)) &&
GetEnvW(L"HOMEPATH", hpath, sizeof(hpath)))
{
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UniFormat(path, size, L"%s%s", drive, hpath);
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}
else
{
#ifdef OS_WIN32
Win32GetCurrentDirW(path, size);
#else // OS_WIN32
UnixGetCurrentDirW(path, size);
#endif // OS_WIN32
}
}
}
// Get the environment variable string
bool GetEnv(char *name, char *data, UINT size)
{
char *ret;
// Validate arguments
if (name == NULL || data == NULL)
{
return false;
}
StrCpy(data, size, "");
ret = getenv(name);
if (ret == NULL)
{
return false;
}
StrCpy(data, size, ret);
return true;
}
bool GetEnvW(wchar_t *name, wchar_t *data, UINT size)
{
#ifdef OS_WIN32
return GetEnvW_ForWin32(name, data, size);
#else // OS_WIN32
return GetEnvW_ForUnix(name, data, size);
#endif // OS_WIN32
}
#ifdef OS_WIN32
bool GetEnvW_ForWin32(wchar_t *name, wchar_t *data, UINT size)
{
wchar_t *ret;
// Validate arguments
if (name == NULL || data == NULL)
{
return false;
}
if (IsNt() == false)
{
bool ret;
char *name_a = CopyUniToStr(name);
char data_a[MAX_SIZE];
ret = GetEnv(name_a, data_a, sizeof(data_a));
if (ret)
{
StrToUni(data, size, data_a);
}
Free(name_a);
return ret;
}
UniStrCpy(data, size, L"");
ret = _wgetenv(name);
if (ret == NULL)
{
return false;
}
UniStrCpy(data, size, ret);
return true;
}
#endif // OS_WIN32
#ifdef OS_UNIX
bool GetEnvW_ForUnix(wchar_t *name, wchar_t *data, UINT size)
{
char *name_a;
bool ret;
char data_a[MAX_SIZE];
// Validate arguments
if (name == NULL || data == NULL)
{
return false;
}
name_a = CopyUniToUtf(name);
ret = GetEnv(name_a, data_a, sizeof(data_a));
if (ret)
{
UtfToUni(data, size, data_a);
}
Free(name_a);
return ret;
}
#endif // OS_UNIX
// Get the memory information
void GetMemInfo(MEMINFO *info)
{
OSGetMemInfo(info);
}
// Start the single-instance
INSTANCE *NewSingleInstance(char *instance_name)
{
return NewSingleInstanceEx(instance_name, false);
}
INSTANCE *NewSingleInstanceEx(char *instance_name, bool user_local)
{
char name[MAX_SIZE];
INSTANCE *ret;
void *data;
if (instance_name != NULL)
{
if (user_local == false)
{
HashInstanceName(name, sizeof(name), instance_name);
}
else
{
HashInstanceNameLocal(name, sizeof(name), instance_name);
}
data = OSNewSingleInstance(name);
}
else
{
data = OSNewSingleInstance(NULL);
}
if (data == NULL)
{
return NULL;
}
ret = ZeroMalloc(sizeof(INSTANCE));
if (instance_name != NULL)
{
ret->Name = CopyStr(instance_name);
}
ret->pData = data;
return ret;
}
// Release of single instance
void FreeSingleInstance(INSTANCE *inst)
{
// Validate arguments
if (inst == NULL)
{
return;
}
OSFreeSingleInstance(inst->pData);
if (inst->Name != NULL)
{
Free(inst->Name);
}
Free(inst);
}
// Hashing the instance name
void HashInstanceName(char *name, UINT size, char *instance_name)
{
char tmp[MAX_SIZE];
UCHAR hash[SHA1_SIZE];
char key[11];
// Validate arguments
if (name == NULL || instance_name == NULL)
{
return;
}
StrCpy(tmp, sizeof(tmp), instance_name);
Trim(tmp);
StrUpper(tmp);
Sha0(hash, tmp, StrLen(tmp));
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BinToStr(key, sizeof(key), hash, 5);
key[10] = 0;
Format(name, size, "VPN-%s", key);
if (OS_IS_WINDOWS_NT(GetOsInfo()->OsType))
{
if (GET_KETA(GetOsInfo()->OsType, 100) >= 2 ||
GetOsInfo()->OsType == OSTYPE_WINDOWS_NT_4_TERMINAL_SERVER)
{
StrCpy(tmp, sizeof(tmp), name);
Format(name, size, "Global\\%s", tmp);
}
}
}
void HashInstanceNameLocal(char *name, UINT size, char *instance_name)
{
char tmp[MAX_SIZE];
UCHAR hash[SHA1_SIZE];
char key[11];
// Validate arguments
if (name == NULL || instance_name == NULL)
{
return;
}
StrCpy(tmp, sizeof(tmp), instance_name);
Trim(tmp);
StrUpper(tmp);
Sha0(hash, tmp, StrLen(tmp));
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BinToStr(key, sizeof(key), hash, 5);
key[10] = 0;
Format(name, size, "VPN-%s", key);
if (OS_IS_WINDOWS_NT(GetOsInfo()->OsType))
{
if (GET_KETA(GetOsInfo()->OsType, 100) >= 2 ||
GetOsInfo()->OsType == OSTYPE_WINDOWS_NT_4_TERMINAL_SERVER)
{
StrCpy(tmp, sizeof(tmp), name);
Format(name, size, "Local\\%s", tmp);
}
}
}
// Run the process
bool Run(char *filename, char *arg, bool hide, bool wait)
{
// Validate arguments
if (filename == NULL)
{
return false;
}
return OSRun(filename, arg, hide, wait);
}
bool RunW(wchar_t *filename, wchar_t *arg, bool hide, bool wait)
{
// Validate arguments
if (filename == NULL)
{
return false;
}
return OSRunW(filename, arg, hide, wait);
}
// Date and time related functions
void GetDateTimeStr64Uni(wchar_t *str, UINT size, UINT64 sec64)
{
char tmp[MAX_SIZE];
if (str == NULL)
{
return;
}
GetDateTimeStr64(tmp, sizeof(tmp), sec64);
StrToUni(str, size, tmp);
}
void GetDateTimeStr64(char *str, UINT size, UINT64 sec64)
{
SYSTEMTIME st;
UINT64ToSystem(&st, sec64);
GetDateTimeStr(str, size, &st);
}
void GetDateTimeStrMilli64(char *str, UINT size, UINT64 sec64)
{
SYSTEMTIME st;
UINT64ToSystem(&st, sec64);
GetDateTimeStrMilli(str, size, &st);
}
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void GetDateTimeStrMilli64ForFileName(char *str, UINT size, UINT64 sec64)
{
SYSTEMTIME st;
UINT64ToSystem(&st, sec64);
GetDateTimeStrMilliForFileName(str, size, &st);
}
void GetDateTimeStrMilliForFileName(char *str, UINT size, SYSTEMTIME *tm)
{
Format(str, size, "%04u%02u%02u_%02u%02u%02u",
tm->wYear, tm->wMonth, tm->wDay, tm->wHour, tm->wMinute, tm->wSecond);
}
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void GetDateStr64(char *str, UINT size, UINT64 sec64)
{
SYSTEMTIME st;
if (sec64 == 0)
{
StrCpy(str, size, "(Unknown)");
return;
}
UINT64ToSystem(&st, sec64);
GetDateStr(str, size, &st);
}
void GetDateTimeStrEx64(wchar_t *str, UINT size, UINT64 sec64, LOCALE *locale)
{
SYSTEMTIME st;
if (locale == NULL)
{
locale = &current_locale;
}
if (sec64 == 0 || SystemToLocal64(sec64) == 0 || LocalToSystem64(sec64) == 0)
{
UniStrCpy(str, size, locale->Unknown);
return;
}
UINT64ToSystem(&st, sec64);
GetDateTimeStrEx(str, size, &st, locale);
}
void GetDateStrEx64(wchar_t *str, UINT size, UINT64 sec64, LOCALE *locale)
{
SYSTEMTIME st;
if (locale == NULL)
{
locale = &current_locale;
}
if (sec64 == 0 || SystemToLocal64(sec64) == 0 || LocalToSystem64(sec64) == 0)
{
UniStrCpy(str, size, locale->Unknown);
return;
}
UINT64ToSystem(&st, sec64);
GetDateStrEx(str, size, &st, locale);
}
void GetTimeStrMilli64(char *str, UINT size, UINT64 sec64)
{
SYSTEMTIME st;
if (sec64 == 0 || SystemToLocal64(sec64) == 0 || LocalToSystem64(sec64) == 0)
{
StrCpy(str, size, "(Unknown)");
return;
}
UINT64ToSystem(&st, sec64);
GetTimeStrMilli(str, size, &st);
}
// Convert to a time to be used safely in the current POSIX implementation
UINT64 SafeTime64(UINT64 sec64)
{
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return MAKESURE(sec64, 0, 4102243323123ULL);
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}
// Thread pool
static SK *thread_pool = NULL;
static COUNTER *thread_count = NULL;
// Initialization of thread pool
void InitThreading()
{
thread_pool = NewSk();
thread_count = NewCounter();
}
// Release of thread pool
void FreeThreading()
{
while (true)
{
if (Count(thread_count) == 0)
{
break;
}
SleepThread(25);
}
while (true)
{
THREAD_POOL_DATA *pd;
THREAD *t = Pop(thread_pool);
if (t == NULL)
{
break;
}
pd = (THREAD_POOL_DATA *)t->param;
pd->ThreadProc = NULL;
Set(pd->Event);
WaitThreadInternal(t);
pd = (THREAD_POOL_DATA *)t->param;
ReleaseEvent(pd->Event);
ReleaseEvent(pd->InitFinishEvent);
ReleaseThreadInternal(t);
Free(pd);
}
ReleaseSk(thread_pool);
DeleteCounter(thread_count);
thread_count = NULL;
}
// Thread pool procedure
void ThreadPoolProc(THREAD *t, void *param)
{
THREAD_POOL_DATA *pd;
// Validate arguments
if (t == NULL)
{
return;
}
pd = (THREAD_POOL_DATA *)param;
NoticeThreadInitInternal(t);
while (true)
{
THREAD *thread;
UINT i, num;
EVENT **ee;
// Wait for the next job
Wait(pd->Event, INFINITE);
if (pd->ThreadProc == NULL)
{
// Stop the pool thread
break;
}
thread = pd->Thread;
thread->ThreadId = ThreadId();
// Initialization is completed
Set(pd->InitFinishEvent);
// Set the thread name
if (thread->Name != NULL)
{
SetThreadName(thread->ThreadId, thread->Name, thread->param);
}
else
{
SetThreadName(thread->ThreadId, "Unknown", 0);
}
// Run the thread procedure
pd->ThreadProc(pd->Thread, thread->param);
// Set the thread name
SetThreadName(thread->ThreadId, NULL, 0);
pd->Thread->Stopped = true;
thread->PoolHalting = true;
// Set the waiting event list
LockList(thread->PoolWaitList);
{
num = LIST_NUM(thread->PoolWaitList);
ee = ToArray(thread->PoolWaitList);
DeleteAll(thread->PoolWaitList);
}
UnlockList(thread->PoolWaitList);
for (i = 0;i < num;i++)
{
EVENT *e = ee[i];
Set(e);
ReleaseEvent(e);
}
Free(ee);
while (true)
{
if (Count(thread->ref->c) <= 1)
{
break;
}
Wait(thread->release_event, 256);
}
ReleaseThread(thread);
#ifdef OS_WIN32
// For Win32: Recover the priority of the thread
MsRestoreThreadPriority();
#endif // OS_WIN32
// Register the thread itself to the thread pool
LockSk(thread_pool);
{
Push(thread_pool, t);
}
UnlockSk(thread_pool);
Dec(thread_count);
}
}
// Set the thread name
void SetThreadName(UINT thread_id, char *name, void *param)
{
#ifdef OS_WIN32
if (IsDebug())
{
char tmp[MAX_SIZE];
if (name == NULL)
{
strcpy(tmp, "idle");
}
else
{
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sprintf(tmp, "%s (0x%x)", name, (UINT)param);
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}
Win32SetThreadName(thread_id, tmp);
}
#else // OS_WIN32
#ifdef _DEBUG
#ifdef PR_SET_NAME
char tmp[MAX_SIZE];
if (name == NULL)
{
strcpy(tmp, "idle");
}
else
{
sprintf(tmp, "%s (%p)", name, param);
}
tmp[15] = 0;
prctl(PR_SET_NAME, (unsigned long)tmp, 0, 0, 0);
#endif // PR_SET_NAME
#endif // _DEBUG
#endif // OS_WIN32
}
// Thread creation (pool)
THREAD *NewThreadNamed(THREAD_PROC *thread_proc, void *param, char *name)
{
THREAD *host = NULL;
THREAD_POOL_DATA *pd = NULL;
THREAD *ret;
// Validate arguments
if (thread_proc == NULL)
{
return NULL;
}
Inc(thread_count);
LockSk(thread_pool);
{
// Examine whether there is a thread that is currently vacant in the pool
host = Pop(thread_pool);
}
UnlockSk(thread_pool);
if (host == NULL)
{
// Create a new thread because a vacant thread is not found
pd = ZeroMalloc(sizeof(THREAD_POOL_DATA));
pd->Event = NewEvent();
pd->InitFinishEvent = NewEvent();
host = NewThreadInternal(ThreadPoolProc, pd);
WaitThreadInitInternal(host);
}
else
{
pd = (THREAD_POOL_DATA *)host->param;
}
// Creating a thread pool
ret = ZeroMalloc(sizeof(THREAD));
ret->ref = NewRef();
ret->thread_proc = thread_proc;
ret->param = param;
ret->pData = NULL;
ret->init_finished_event = NewEvent();
ret->PoolThread = true;
ret->PoolWaitList = NewList(NULL);
ret->PoolHostThread = host;
ret->release_event = NewEvent();
if (IsEmptyStr(name) == false)
{
ret->Name = CopyStr(name);
}
// Run
pd->ThreadProc = thread_proc;
pd->Thread = ret;
AddRef(ret->ref);
Set(pd->Event);
Wait(pd->InitFinishEvent, INFINITE);
current_num_thread++;
// Debug("current_num_thread = %u\n", current_num_thread);
return ret;
}
// Clean up of thread (pool)
void CleanupThread(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
ReleaseEvent(t->init_finished_event);
ReleaseEvent(t->release_event);
ReleaseList(t->PoolWaitList);
if (t->Name != NULL)
{
Free(t->Name);
}
Free(t);
current_num_thread--;
//Debug("current_num_thread = %u\n", current_num_thread);
}
// Release thread (pool)
void ReleaseThread(THREAD *t)
{
UINT ret;
EVENT *e;
// Validate arguments
if (t == NULL)
{
return;
}
e = t->release_event;
if (e != NULL)
{
AddRef(e->ref);
}
ret = Release(t->ref);
Set(e);
ReleaseEvent(e);
if (ret == 0)
{
CleanupThread(t);
}
}
// Notify the completion of the thread initialization (pool)
void NoticeThreadInit(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
// Notification
Set(t->init_finished_event);
}
// Wait the completion of the thread initialization (pool)
void WaitThreadInit(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
// KS
KS_INC(KS_WAITFORTHREAD_COUNT);
// Wait
Wait(t->init_finished_event, INFINITE);
}
// Wait for the termination of the thread (pool)
bool WaitThread(THREAD *t, UINT timeout)
{
bool ret = false;
EVENT *e = NULL;
// Validate arguments
if (t == NULL)
{
return false;
}
LockList(t->PoolWaitList);
{
if (t->PoolHalting)
{
// Has already been stopped
ret = true;
}
else
{
// Register the completion notifying event to the list
e = NewEvent();
AddRef(e->ref);
Insert(t->PoolWaitList, e);
}
}
UnlockList(t->PoolWaitList);
if (e != NULL)
{
// Wait Event
ret = Wait(e, timeout);
LockList(t->PoolWaitList);
{
if (Delete(t->PoolWaitList, e))
{
ReleaseEvent(e);
}
}
UnlockList(t->PoolWaitList);
ReleaseEvent(e);
}
return ret;
}
// Get Thread ID
UINT ThreadId()
{
return OSThreadId();
}
// Creating a thread
THREAD *NewThreadInternal(THREAD_PROC *thread_proc, void *param)
{
THREAD *t;
UINT retry = 0;
// Validate arguments
if (thread_proc == NULL)
{
return NULL;
}
// Initialize Thread object
t = ZeroMalloc(sizeof(THREAD));
t->init_finished_event = NewEvent();
t->param = param;
t->ref = NewRef();
t->thread_proc = thread_proc;
// Wait until the OS to initialize the thread
while (true)
{
if ((retry++) > 60)
{
printf("\n\n*** error: new thread create failed.\n\n");
AbortExit();
}
if (OSInitThread(t))
{
break;
}
SleepThread(500);
}
// KS
KS_INC(KS_NEWTHREAD_COUNT);
return t;
}
// Release of thread
void ReleaseThreadInternal(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
if (Release(t->ref) == 0)
{
CleanupThreadInternal(t);
}
}
// Clean up of the thread
void CleanupThreadInternal(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
// Release of the thread
OSFreeThread(t);
// Release the event
ReleaseEvent(t->init_finished_event);
// Memory release
Free(t);
// KS
KS_INC(KS_FREETHREAD_COUNT);
}
// Wait for the termination of the thread
bool WaitThreadInternal(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return false;
}
return OSWaitThread(t);
}
// Notify that the thread initialization is complete
void NoticeThreadInitInternal(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
// Notify
Set(t->init_finished_event);
}
// Wait for completion of thread initialization
void WaitThreadInitInternal(THREAD *t)
{
// Validate arguments
if (t == NULL)
{
return;
}
// KS
KS_INC(KS_WAITFORTHREAD_COUNT);
// Wait
Wait(t->init_finished_event, INFINITE);
}
// Get the date and time string by using the locale information
void GetDateTimeStrEx(wchar_t *str, UINT size, SYSTEMTIME *st, LOCALE *locale)
{
wchar_t tmp1[MAX_SIZE];
wchar_t tmp2[MAX_SIZE];
// Validate arguments
if (str == NULL || st == NULL)
{
return;
}
GetDateStrEx(tmp1, sizeof(tmp1), st, locale);
GetTimeStrEx(tmp2, sizeof(tmp2), st, locale);
UniFormat(str, size, L"%s %s", tmp1, tmp2);
}
// Get the time string by using the locale information
void GetTimeStrEx(wchar_t *str, UINT size, SYSTEMTIME *st, LOCALE *locale)
{
wchar_t *tag = L"%02u%s%02u%s%02u%s";
// Validate arguments
if (str == NULL || st == NULL)
{
return;
}
if (_GETLANG() == SE_LANG_JAPANESE || _GETLANG() == SE_LANG_CHINESE_ZH)
{
tag = L"%2u%s%2u%s%2u%s";
}
locale = (locale != NULL ? locale : &current_locale);
UniFormat(str, size,
tag,
st->wHour, locale->HourStr,
st->wMinute, locale->MinuteStr,
st->wSecond, locale->SecondStr);
}
// Get a date string by using the locale information
void GetDateStrEx(wchar_t *str, UINT size, SYSTEMTIME *st, LOCALE *locale)
{
wchar_t *tag = L"%04u%s%02u%s%02u%s (%s)";
// Validate arguments
if (str == NULL || st == NULL)
{
return;
}
if (_GETLANG() == SE_LANG_JAPANESE || _GETLANG() == SE_LANG_CHINESE_ZH)
{
tag = L"%4u%s%2u%s%2u%s(%s)";
}
locale = (locale != NULL ? locale : &current_locale);
UniFormat(str, size,
tag,
st->wYear, locale->YearStr,
st->wMonth, locale->MonthStr,
st->wDay, locale->DayStr,
locale->DayOfWeek[st->wDayOfWeek]);
}
// Get the time string to milliseconds (for example, 12:34:56.789)
void GetTimeStrMilli(char *str, UINT size, SYSTEMTIME *st)
{
// Validate arguments
if (st == NULL || str == NULL)
{
return;
}
Format(str, size, "%02u:%02u:%02u.%03u",
st->wHour, st->wMinute, st->wSecond, st->wMilliseconds);
}
// Get the date string (example: 2004/07/23)
void GetDateStr(char *str, UINT size, SYSTEMTIME *st)
{
// Validate arguments
if (str == NULL || st == NULL)
{
return;
}
Format(str, size, "%04u-%02u-%02u",
st->wYear, st->wMonth, st->wDay);
}
// Get the date and time string (example: 2004/07/23 12:34:56)
void GetDateTimeStr(char *str, UINT size, SYSTEMTIME *st)
{
// Validate arguments
if (str == NULL || st == NULL)
{
return;
}
Format(str, size, "%04u-%02u-%02u %02u:%02u:%02u",
st->wYear, st->wMonth, st->wDay,
st->wHour, st->wMinute, st->wSecond);
}
// Get the date and time string in milliseconds (example: 2004/07/23 12:34:56.789)
void GetDateTimeStrMilli(char *str, UINT size, SYSTEMTIME *st)
{
// Validate arguments
if (str == NULL || st == NULL)
{
return;
}
Format(str, size, "%04u-%02u-%02u %02u:%02u:%02u.%03u",
st->wYear, st->wMonth, st->wDay,
st->wHour, st->wMinute, st->wSecond,
st->wMilliseconds);
}
// Convert string RFC3339 format (example: 2017-09-27T18:25:55.434-9:00) to UINT64
UINT64 DateTimeStrRFC3339ToSystemTime64(char *str)
{
SYSTEMTIME st;
if (DateTimeStrRFC3339ToSystemTime(&st, str))
{
return SystemToUINT64(&st);
}
else
{
return 0;
}
}
// Convert string RFC3339 format (example: 2017-09-27T18:25:55.434-9:00) to SYSTEMTIME
bool DateTimeStrRFC3339ToSystemTime(SYSTEMTIME *st, char *str)
{
bool ok = false;
UINT index_plus;
char tmp[MAX_PATH];
Zero(st, sizeof(SYSTEMTIME));
if (st == NULL || str == NULL)
{
return false;
}
StrCpy(tmp, sizeof(tmp), str);
index_plus = SearchStrEx(tmp, "+", 0, false);
if (index_plus != INFINITE)
{
tmp[index_plus] = 0;
}
if (StrLen(tmp) >= 19)
{
if (tmp[4] == '-' && tmp[7] == '-' && tmp[10] == 'T' && tmp[13] == ':' &&
tmp[16] == ':')
{
char str_year[16], str_month[16], str_day[16], str_hour[16], str_minute[16],
str_second[16], str_msec[16];
StrCpy(str_year, sizeof(str_year), tmp + 0);
str_year[4] = 0;
StrCpy(str_month, sizeof(str_month), tmp + 5);
str_month[2] = 0;
StrCpy(str_day, sizeof(str_day), tmp + 8);
str_day[2] = 0;
StrCpy(str_hour, sizeof(str_hour), tmp + 11);
str_hour[2] = 0;
StrCpy(str_minute, sizeof(str_minute), tmp + 14);
str_minute[2] = 0;
StrCpy(str_second, sizeof(str_second), tmp + 17);
str_second[2] = 0;
str_msec[0] = 0;
if (StrLen(tmp) >= 21 && tmp[19] == '.')
{
StrCpy(str_msec, sizeof(str_msec), tmp + 20);
str_msec[StrLen(tmp) - 21] = 0;
while (StrLen(str_msec) < 3)
{
StrCat(str_msec, sizeof(str_msec), "0");
}
str_msec[3] = 0;
}
st->wYear = ToInt(str_year);
st->wMonth = ToInt(str_month);
st->wDay = ToInt(str_day);
st->wHour = ToInt(str_hour);
st->wMinute = ToInt(str_minute);
st->wSecond = ToInt(str_second);
st->wMilliseconds = ToInt(str_msec);
NormalizeSystem(st);
ok = true;
}
}
return ok;
}
// Get the date and time string in RFC3339 format (example: 2017-09-27T18:25:55.434-9:00)
void GetDateTimeStrRFC3339(char *str, UINT size, SYSTEMTIME *st, int timezone_min){
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// Validate arguments
if (str == NULL || st == NULL)
{
ClearStr(str, size);
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return;
}
if(timezone_min == 0){
Format(str, size, "%04u-%02u-%02uT%02u:%02u:%02u.%03uZ",
st->wYear, st->wMonth, st->wDay,
st->wHour, st->wMinute, st->wSecond,
st->wMilliseconds);
}else{
Format(str, size, "%04u-%02u-%02uT%02u:%02u:%02u.%03u%+02d:%02d",
st->wYear, st->wMonth, st->wDay,
st->wHour, st->wMinute, st->wSecond,
st->wMilliseconds, timezone_min/60, timezone_min%60);
}
}
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// Get the time string (in milliseconds)
void GetSpanStrMilli(char *str, UINT size, UINT64 sec64)
{
char tmp[MAX_SIZE];
// Validate arguments
if (str == NULL)
{
return;
}
StrCpy(tmp, sizeof(tmp), "");
if (sec64 >= (UINT64)(1000 * 3600 * 24))
{
Format(tmp, sizeof(tmp), "%u:", (UINT)(sec64 / (UINT64)(1000 * 3600 * 24)));
}
Format(tmp, sizeof(tmp), "%s%02u:%02u:%02u.%03u", tmp,
(UINT)(sec64 % (UINT64)(1000 * 60 * 60 * 24)) / (1000 * 60 * 60),
(UINT)(sec64 % (UINT64)(1000 * 60 * 60)) / (1000 * 60),
(UINT)(sec64 % (UINT64)(1000 * 60)) / 1000,
(UINT)(sec64 % (UINT64)(1000)));
Trim(tmp);
StrCpy(str, size, tmp);
}
// Set the locale information
void SetLocale(wchar_t *str)
{
wchar_t *set_locale_str;
LOCALE tmp;
if (str != NULL)
{
set_locale_str = str;
}
else
{
set_locale_str = default_locale_str;
}
if (LoadLocale(&tmp, set_locale_str) == false)
{
if (LoadLocale(&tmp, default_locale_str) == false)
{
return;
}
}
Copy(&current_locale, &tmp, sizeof(LOCALE));
}
#define COPY_LOCALE_STR(dest, size, src) UniStrCpy(dest, size, UniStrCmp(src, L"$") == 0 ? L"" : src)
// Read the locale information
bool LoadLocale(LOCALE *locale, wchar_t *str)
{
UNI_TOKEN_LIST *tokens;
UINT i;
// Validate arguments
if (locale == NULL || str == NULL)
{
return false;
}
// Analysis of the token
tokens = UniParseToken(str, L" ");
if (tokens->NumTokens != 18)
{
UniFreeToken(tokens);
return false;
}
// Set to the structure
Zero(locale, sizeof(LOCALE));
COPY_LOCALE_STR(locale->YearStr, sizeof(locale->YearStr), tokens->Token[0]);
COPY_LOCALE_STR(locale->MonthStr, sizeof(locale->MonthStr), tokens->Token[1]);
COPY_LOCALE_STR(locale->DayStr, sizeof(locale->DayStr), tokens->Token[2]);
COPY_LOCALE_STR(locale->HourStr, sizeof(locale->HourStr), tokens->Token[3]);
COPY_LOCALE_STR(locale->MinuteStr, sizeof(locale->MinuteStr), tokens->Token[4]);
COPY_LOCALE_STR(locale->SecondStr, sizeof(locale->SecondStr), tokens->Token[5]);
for (i = 0;i < 7;i++)
{
COPY_LOCALE_STR(locale->DayOfWeek[i], sizeof(locale->DayOfWeek[i]),
tokens->Token[6 + i]);
}
COPY_LOCALE_STR(locale->SpanDay, sizeof(locale->SpanDay), tokens->Token[13]);
COPY_LOCALE_STR(locale->SpanHour, sizeof(locale->SpanHour), tokens->Token[14]);
COPY_LOCALE_STR(locale->SpanMinute, sizeof(locale->SpanMinute), tokens->Token[15]);
COPY_LOCALE_STR(locale->SpanSecond, sizeof(locale->SpanSecond), tokens->Token[16]);
COPY_LOCALE_STR(locale->Unknown, sizeof(locale->Unknown), tokens->Token[17]);
UniFreeToken(tokens);
return true;
}
// Convert SYSTEMTIME into DOS date
USHORT SystemToDosDate(SYSTEMTIME *st)
{
return (USHORT)(
((UINT)(st->wYear - 1980) << 9) |
((UINT)st->wMonth<< 5) |
(UINT)st->wDay);
}
USHORT System64ToDosDate(UINT64 i)
{
SYSTEMTIME st;
UINT64ToSystem(&st, i);
return SystemToDosDate(&st);
}
// Convert SYSTEMTIME into DOS time
USHORT SystemToDosTime(SYSTEMTIME *st)
{
return (USHORT)(
((UINT)st->wHour << 11) |
((UINT)st->wMinute << 5) |
((UINT)st->wSecond >> 1));
}
USHORT System64ToDosTime(UINT64 i)
{
SYSTEMTIME st;
UINT64ToSystem(&st, i);
return SystemToDosTime(&st);
}
// Convert the tm to the SYSTEMTIME
void TmToSystem(SYSTEMTIME *st, struct tm *t)
{
struct tm tmp;
// Validate arguments
if (st == NULL || t == NULL)
{
return;
}
Copy(&tmp, t, sizeof(struct tm));
NormalizeTm(&tmp);
Zero(st, sizeof(SYSTEMTIME));
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st->wYear = MAKESURE(tmp.tm_year + 1900, 1970, 2099);
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st->wMonth = MAKESURE(tmp.tm_mon + 1, 1, 12);
st->wDay = MAKESURE(tmp.tm_mday, 1, 31);
st->wDayOfWeek = MAKESURE(tmp.tm_wday, 0, 6);
st->wHour = MAKESURE(tmp.tm_hour, 0, 23);
st->wMinute = MAKESURE(tmp.tm_min, 0, 59);
st->wSecond = MAKESURE(tmp.tm_sec, 0, 59);
st->wMilliseconds = 0;
}
// Convert the SYSTEMTIME to tm
void SystemToTm(struct tm *t, SYSTEMTIME *st)
{
// Validate arguments
if (t == NULL || st == NULL)
{
return;
}
Zero(t, sizeof(struct tm));
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t->tm_year = MAKESURE(st->wYear, 1970, 2099) - 1900;
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t->tm_mon = MAKESURE(st->wMonth, 1, 12) - 1;
t->tm_mday = MAKESURE(st->wDay, 1, 31);
t->tm_hour = MAKESURE(st->wHour, 0, 23);
t->tm_min = MAKESURE(st->wMinute, 0, 59);
t->tm_sec = MAKESURE(st->wSecond, 0, 59);
t->tm_isdst = -1;
NormalizeTm(t);
}
// Convert the time_t to SYSTEMTIME
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void TimeToSystem(SYSTEMTIME *st, time_64t t)
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{
struct tm tmp;
// Validate arguments
if (st == NULL)
{
return;
}
TimeToTm(&tmp, t);
TmToSystem(st, &tmp);
}
// Convert the SYSTEMTIME to time_t
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time_64t SystemToTime(SYSTEMTIME *st)
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{
struct tm t;
// Validate arguments
if (st == NULL)
{
return 0;
}
SystemToTm(&t, st);
return TmToTime(&t);
}
// Convert the tm to time_t
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time_64t TmToTime(struct tm *t)
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{
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time_64t tmp;
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// Validate arguments
if (t == NULL)
{
return 0;
}
tmp = c_mkgmtime(t);
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if (tmp == (time_64t)-1)
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{
return 0;
}
return tmp;
}
// Convert time_t to tm
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void TimeToTm(struct tm *t, time_64t time)
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{
// Validate arguments
if (t == NULL)
{
return;
}
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Zero(t, sizeof(struct tm));
c_gmtime_r(&time, t);
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}
// Normalize the tm
void NormalizeTm(struct tm *t)
{
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time_64t tmp;
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// Validate arguments
if (t == NULL)
{
return;
}
tmp = c_mkgmtime(t);
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if (tmp == (time_64t)-1)
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{
return;
}
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c_gmtime_r(&tmp, t);
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}
// Normalize the SYSTEMTIME
void NormalizeSystem(SYSTEMTIME *st)
{
UINT64 sec64;
// Validate arguments
if (st == NULL)
{
return;
}
sec64 = SystemToUINT64(st);
UINT64ToSystem(st, sec64);
}
// Convert a 64-bit local time to a system time
UINT64 LocalToSystem64(UINT64 t)
{
SYSTEMTIME st;
UINT64ToSystem(&st, t);
LocalToSystem(&st, &st);
return SystemToUINT64(&st);
}
// Convert the 64bit system time to local time
UINT64 SystemToLocal64(UINT64 t)
{
SYSTEMTIME st;
UINT64ToSystem(&st, t);
SystemToLocal(&st, &st);
return SystemToUINT64(&st);
}
// Convert local time to system time
void LocalToSystem(SYSTEMTIME *system, SYSTEMTIME *local)
{
UINT64 sec64;
// Validate arguments
if (local == NULL || system == NULL)
{
return;
}
sec64 = (UINT64)((INT64)SystemToUINT64(local) - GetTimeDiffEx(local, true));
UINT64ToSystem(system, sec64);
}
// Convert the system time to local time
void SystemToLocal(SYSTEMTIME *local, SYSTEMTIME *system)
{
UINT64 sec64;
// Validate arguments
if (local == NULL || system == NULL)
{
return;
}
sec64 = (UINT64)((INT64)SystemToUINT64(system) + GetTimeDiffEx(system, false));
UINT64ToSystem(local, sec64);
}
// Get the time difference between the local time and the system time based on the specified time
INT64 GetTimeDiffEx(SYSTEMTIME *basetime, bool local_time)
{
time_t tmp;
struct tm t1, t2;
SYSTEMTIME snow;
struct tm now;
SYSTEMTIME s1, s2;
INT64 ret;
Copy(&snow, basetime, sizeof(SYSTEMTIME));
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if (sizeof(time_t) == 4)
{
if (snow.wYear >= 2038)
{
// For old systems: avoid the 2038-year problem
snow.wYear = 2037;
}
}
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SystemToTm(&now, &snow);
if (local_time == false)
{
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tmp = (time_t)c_mkgmtime(&now);
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}
else
{
tmp = mktime(&now);
}
if (tmp == (time_t)-1)
{
return 0;
}
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#ifndef OS_UNIX
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Copy(&t1, localtime(&tmp), sizeof(struct tm));
Copy(&t2, gmtime(&tmp), sizeof(struct tm));
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#else // OS_UNIX
localtime_r(&tmp, &t1);
gmtime_r(&tmp, &t2);
#endif // OS_UNIX
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TmToSystem(&s1, &t1);
TmToSystem(&s2, &t2);
ret = (INT)SystemToUINT64(&s1) - (INT)SystemToUINT64(&s2);
return ret;
}
// Convert UINT64 to the SYSTEMTIME
void UINT64ToSystem(SYSTEMTIME *st, UINT64 sec64)
{
UINT64 tmp64;
UINT sec, millisec;
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time_64t time;
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// Validate arguments
if (st == NULL)
{
return;
}
sec64 = SafeTime64(sec64 + 32400000ULL);
tmp64 = sec64 / (UINT64)1000;
millisec = (UINT)(sec64 - tmp64 * (UINT64)1000);
sec = (UINT)tmp64;
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time = (time_64t)sec;
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TimeToSystem(st, time);
st->wMilliseconds = (WORD)millisec;
}
// Convert the SYSTEMTIME to UINT64
UINT64 SystemToUINT64(SYSTEMTIME *st)
{
UINT64 sec64;
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time_64t time;
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// Validate arguments
if (st == NULL)
{
return 0;
}
time = SystemToTime(st);
//For times before 1970-01-01, clamp to the minimum
//because we have to return an unsigned integer.
//This is less wrong than casting it to UINT64
//and returning a time far in the future.
//For some reason we subtract 9 hours below, so
//account for that here.
if( time < 32400000LL ) return 0;
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sec64 = (UINT64)time * (UINT64)1000;
sec64 += st->wMilliseconds;
return sec64 - 32400000ULL;
}
// Get local time in UINT64
UINT64 LocalTime64()
{
SYSTEMTIME s;
LocalTime(&s);
return SystemToUINT64(&s);
}
// Get the system time in UINT64
UINT64 SystemTime64()
{
SYSTEMTIME s;
SystemTime(&s);
return SystemToUINT64(&s);
}
// Get local time
void LocalTime(SYSTEMTIME *st)
{
SYSTEMTIME tmp;
// Validate arguments
if (st == NULL)
{
return;
}
SystemTime(&tmp);
SystemToLocal(st, &tmp);
}
// Get the System Time
void SystemTime(SYSTEMTIME *st)
{
// Validate arguments
if (st == NULL)
{
return;
}
OSGetSystemTime(st);
// KS
KS_INC(KS_GETTIME_COUNT);
}
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time_64t c_mkgmtime(struct tm *tm)
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{
int years, months, days, hours, minutes, seconds;
years = tm->tm_year + 1900; /* year - 1900 -> year */
months = tm->tm_mon; /* 0..11 */
days = tm->tm_mday - 1; /* 1..31 -> 0..30 */
hours = tm->tm_hour; /* 0..23 */
minutes = tm->tm_min; /* 0..59 */
seconds = tm->tm_sec; /* 0..61 in ANSI C. */
ADJUST_TM(seconds, minutes, 60);
ADJUST_TM(minutes, hours, 60);
ADJUST_TM(hours, days, 24);
ADJUST_TM(months, years, 12);
if (days < 0)
do {
if (--months < 0) {
--years;
months = 11;
}
days += monthlen(months, years);
} while (days < 0);
else
while (days >= monthlen(months, years)) {
days -= monthlen(months, years);
if (++months >= 12) {
++years;
months = 0;
}
}
/* Restore adjusted values in tm structure */
tm->tm_year = years - 1900;
tm->tm_mon = months;
tm->tm_mday = days + 1;
tm->tm_hour = hours;
tm->tm_min = minutes;
tm->tm_sec = seconds;
/* Set `days' to the number of days into the year. */
days += ydays[months] + (months > 1 && leap (years));
tm->tm_yday = days;
/* Now calculate `days' to the number of days since Jan 1, 1970. */
days = (unsigned)days + 365 * (unsigned)(years - 1970) +
(unsigned)(nleap (years));
tm->tm_wday = ((unsigned)days + 4) % 7; /* Jan 1, 1970 was Thursday. */
tm->tm_isdst = 0;
if (years < 1970)
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return (time_64t)-1;
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#if (defined(TM_YEAR_MAX) && defined(TM_MON_MAX) && defined(TM_MDAY_MAX))
#if (defined(TM_HOUR_MAX) && defined(TM_MIN_MAX) && defined(TM_SEC_MAX))
if (years > TM_YEAR_MAX ||
(years == TM_YEAR_MAX &&
(tm->tm_yday > ydays[TM_MON_MAX] + (TM_MDAY_MAX - 1) +
(TM_MON_MAX > 1 && leap (TM_YEAR_MAX)) ||
(tm->tm_yday == ydays[TM_MON_MAX] + (TM_MDAY_MAX - 1) +
(TM_MON_MAX > 1 && leap (TM_YEAR_MAX)) &&
(hours > TM_HOUR_MAX ||
(hours == TM_HOUR_MAX &&
(minutes > TM_MIN_MAX ||
(minutes == TM_MIN_MAX && seconds > TM_SEC_MAX) )))))))
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return (time_64t)-1;
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#endif
#endif
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return (time_64t)(86400L * (unsigned long)(unsigned)days +
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3600L * (unsigned long)hours +
(unsigned long)(60 * minutes + seconds));
}
// Get the system timer
UINT Tick()
{
// KS
KS_INC(KS_GETTICK_COUNT);
return OSGetTick();
}
// Sleep thread
void SleepThread(UINT time)
{
// KS
KS_INC(KS_SLEEPTHREAD_COUNT);
OSSleep(time);
}
// Yield
void YieldCpu()
{
OSYield();
}
// Stop system (abnormal termination)
void AbortExit()
{
#ifdef OS_WIN32
_exit(1);
#else // OS_WIN32
#ifdef RLIMIT_CORE
UnixSetResourceLimit(RLIMIT_CORE, 0);
#endif // RLIMIT_CORE
abort();
#endif // OS_WIN32
}
void AbortExitEx(char *msg)
{
FILE *f;
// Validate arguments
if (msg == NULL)
{
msg = "Unknown Error";
}
f = fopen("abort_error_log.txt", "w");
if (f != NULL)
{
fwrite(msg, 1, strlen(msg), f);
fclose(f);
}
fputs("Fatal Error: ", stdout);
fputs(msg, stdout);
fputs("\r\n", stdout);
#ifdef OS_WIN32
_exit(1);
#else // OS_WIN32
#ifdef RLIMIT_CORE
UnixSetResourceLimit(RLIMIT_CORE, 0);
#endif // RLIMIT_CORE
abort();
#endif // OS_WIN32
}