1
0
mirror of https://github.com/hashcat/hashcat.git synced 2024-11-25 17:38:23 +00:00
hashcat/deps/LZMA-SDK/C/Threads.c
2023-05-17 19:03:13 +02:00

541 lines
12 KiB
C

/* Threads.c -- multithreading library
2021-12-21 : Igor Pavlov : Public domain */
#include "Precomp.h"
#ifdef _WIN32
#ifndef USE_THREADS_CreateThread
#include <process.h>
#endif
#include "Threads.h"
static WRes GetError()
{
DWORD res = GetLastError();
return res ? (WRes)res : 1;
}
static WRes HandleToWRes(HANDLE h) { return (h != NULL) ? 0 : GetError(); }
static WRes BOOLToWRes(BOOL v) { return v ? 0 : GetError(); }
WRes HandlePtr_Close(HANDLE *p)
{
if (*p != NULL)
{
if (!CloseHandle(*p))
return GetError();
*p = NULL;
}
return 0;
}
WRes Handle_WaitObject(HANDLE h)
{
DWORD dw = WaitForSingleObject(h, INFINITE);
/*
(dw) result:
WAIT_OBJECT_0 // 0
WAIT_ABANDONED // 0x00000080 : is not compatible with Win32 Error space
WAIT_TIMEOUT // 0x00000102 : is compatible with Win32 Error space
WAIT_FAILED // 0xFFFFFFFF
*/
if (dw == WAIT_FAILED)
{
dw = GetLastError();
if (dw == 0)
return WAIT_FAILED;
}
return (WRes)dw;
}
#define Thread_Wait(p) Handle_WaitObject(*(p))
WRes Thread_Wait_Close(CThread *p)
{
WRes res = Thread_Wait(p);
WRes res2 = Thread_Close(p);
return (res != 0 ? res : res2);
}
WRes Thread_Create(CThread *p, THREAD_FUNC_TYPE func, LPVOID param)
{
/* Windows Me/98/95: threadId parameter may not be NULL in _beginthreadex/CreateThread functions */
#ifdef USE_THREADS_CreateThread
DWORD threadId;
*p = CreateThread(NULL, 0, func, param, 0, &threadId);
#else
unsigned threadId;
*p = (HANDLE)(_beginthreadex(NULL, 0, func, param, 0, &threadId));
#endif
/* maybe we must use errno here, but probably GetLastError() is also OK. */
return HandleToWRes(*p);
}
WRes Thread_Create_With_Affinity(CThread *p, THREAD_FUNC_TYPE func, LPVOID param, CAffinityMask affinity)
{
#ifdef USE_THREADS_CreateThread
UNUSED_VAR(affinity)
return Thread_Create(p, func, param);
#else
/* Windows Me/98/95: threadId parameter may not be NULL in _beginthreadex/CreateThread functions */
HANDLE h;
WRes wres;
unsigned threadId;
h = (HANDLE)(_beginthreadex(NULL, 0, func, param, CREATE_SUSPENDED, &threadId));
*p = h;
wres = HandleToWRes(h);
if (h)
{
{
// DWORD_PTR prevMask =
SetThreadAffinityMask(h, (DWORD_PTR)affinity);
/*
if (prevMask == 0)
{
// affinity change is non-critical error, so we can ignore it
// wres = GetError();
}
*/
}
{
DWORD prevSuspendCount = ResumeThread(h);
/* ResumeThread() returns:
0 : was_not_suspended
1 : was_resumed
-1 : error
*/
if (prevSuspendCount == (DWORD)-1)
wres = GetError();
}
}
/* maybe we must use errno here, but probably GetLastError() is also OK. */
return wres;
#endif
}
static WRes Event_Create(CEvent *p, BOOL manualReset, int signaled)
{
*p = CreateEvent(NULL, manualReset, (signaled ? TRUE : FALSE), NULL);
return HandleToWRes(*p);
}
WRes Event_Set(CEvent *p) { return BOOLToWRes(SetEvent(*p)); }
WRes Event_Reset(CEvent *p) { return BOOLToWRes(ResetEvent(*p)); }
WRes ManualResetEvent_Create(CManualResetEvent *p, int signaled) { return Event_Create(p, TRUE, signaled); }
WRes AutoResetEvent_Create(CAutoResetEvent *p, int signaled) { return Event_Create(p, FALSE, signaled); }
WRes ManualResetEvent_CreateNotSignaled(CManualResetEvent *p) { return ManualResetEvent_Create(p, 0); }
WRes AutoResetEvent_CreateNotSignaled(CAutoResetEvent *p) { return AutoResetEvent_Create(p, 0); }
WRes Semaphore_Create(CSemaphore *p, UInt32 initCount, UInt32 maxCount)
{
// negative ((LONG)maxCount) is not supported in WIN32::CreateSemaphore()
*p = CreateSemaphore(NULL, (LONG)initCount, (LONG)maxCount, NULL);
return HandleToWRes(*p);
}
WRes Semaphore_OptCreateInit(CSemaphore *p, UInt32 initCount, UInt32 maxCount)
{
// if (Semaphore_IsCreated(p))
{
WRes wres = Semaphore_Close(p);
if (wres != 0)
return wres;
}
return Semaphore_Create(p, initCount, maxCount);
}
static WRes Semaphore_Release(CSemaphore *p, LONG releaseCount, LONG *previousCount)
{ return BOOLToWRes(ReleaseSemaphore(*p, releaseCount, previousCount)); }
WRes Semaphore_ReleaseN(CSemaphore *p, UInt32 num)
{ return Semaphore_Release(p, (LONG)num, NULL); }
WRes Semaphore_Release1(CSemaphore *p) { return Semaphore_ReleaseN(p, 1); }
WRes CriticalSection_Init(CCriticalSection *p)
{
/* InitializeCriticalSection() can raise exception:
Windows XP, 2003 : can raise a STATUS_NO_MEMORY exception
Windows Vista+ : no exceptions */
#ifdef _MSC_VER
__try
#endif
{
InitializeCriticalSection(p);
/* InitializeCriticalSectionAndSpinCount(p, 0); */
}
#ifdef _MSC_VER
__except (EXCEPTION_EXECUTE_HANDLER) { return ERROR_NOT_ENOUGH_MEMORY; }
#endif
return 0;
}
#else // _WIN32
// ---------- POSIX ----------
#ifndef __APPLE__
#ifndef _7ZIP_AFFINITY_DISABLE
// _GNU_SOURCE can be required for pthread_setaffinity_np() / CPU_ZERO / CPU_SET
#define _GNU_SOURCE
#endif
#endif
#include "Threads.h"
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#ifdef _7ZIP_AFFINITY_SUPPORTED
// #include <sched.h>
#endif
// #include <stdio.h>
// #define PRF(p) p
#define PRF(p)
#define Print(s) PRF(printf("\n%s\n", s))
// #include <stdio.h>
WRes Thread_Create_With_CpuSet(CThread *p, THREAD_FUNC_TYPE func, LPVOID param, const CCpuSet *cpuSet)
{
// new thread in Posix probably inherits affinity from parrent thread
Print("Thread_Create_With_CpuSet");
pthread_attr_t attr;
int ret;
// int ret2;
p->_created = 0;
RINOK(pthread_attr_init(&attr));
ret = pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE);
if (!ret)
{
if (cpuSet)
{
#ifdef _7ZIP_AFFINITY_SUPPORTED
/*
printf("\n affinity :");
unsigned i;
for (i = 0; i < sizeof(*cpuSet) && i < 8; i++)
{
Byte b = *((const Byte *)cpuSet + i);
char temp[32];
#define GET_HEX_CHAR(t) ((char)(((t < 10) ? ('0' + t) : ('A' + (t - 10)))))
temp[0] = GET_HEX_CHAR((b & 0xF));
temp[1] = GET_HEX_CHAR((b >> 4));
// temp[0] = GET_HEX_CHAR((b >> 4)); // big-endian
// temp[1] = GET_HEX_CHAR((b & 0xF)); // big-endian
temp[2] = 0;
printf("%s", temp);
}
printf("\n");
*/
// ret2 =
pthread_attr_setaffinity_np(&attr, sizeof(*cpuSet), cpuSet);
// if (ret2) ret = ret2;
#endif
}
ret = pthread_create(&p->_tid, &attr, func, param);
if (!ret)
{
p->_created = 1;
/*
if (cpuSet)
{
// ret2 =
pthread_setaffinity_np(p->_tid, sizeof(*cpuSet), cpuSet);
// if (ret2) ret = ret2;
}
*/
}
}
// ret2 =
pthread_attr_destroy(&attr);
// if (ret2 != 0) ret = ret2;
return ret;
}
WRes Thread_Create(CThread *p, THREAD_FUNC_TYPE func, LPVOID param)
{
return Thread_Create_With_CpuSet(p, func, param, NULL);
}
WRes Thread_Create_With_Affinity(CThread *p, THREAD_FUNC_TYPE func, LPVOID param, CAffinityMask affinity)
{
Print("Thread_Create_WithAffinity");
CCpuSet cs;
unsigned i;
CpuSet_Zero(&cs);
for (i = 0; i < sizeof(affinity) * 8; i++)
{
if (affinity == 0)
break;
if (affinity & 1)
{
CpuSet_Set(&cs, i);
}
affinity >>= 1;
}
return Thread_Create_With_CpuSet(p, func, param, &cs);
}
WRes Thread_Close(CThread *p)
{
// Print("Thread_Close");
int ret;
if (!p->_created)
return 0;
ret = pthread_detach(p->_tid);
p->_tid = 0;
p->_created = 0;
return ret;
}
WRes Thread_Wait_Close(CThread *p)
{
// Print("Thread_Wait_Close");
void *thread_return;
int ret;
if (!p->_created)
return EINVAL;
ret = pthread_join(p->_tid, &thread_return);
// probably we can't use that (_tid) after pthread_join(), so we close thread here
p->_created = 0;
p->_tid = 0;
return ret;
}
static WRes Event_Create(CEvent *p, int manualReset, int signaled)
{
RINOK(pthread_mutex_init(&p->_mutex, NULL));
RINOK(pthread_cond_init(&p->_cond, NULL));
p->_manual_reset = manualReset;
p->_state = (signaled ? True : False);
p->_created = 1;
return 0;
}
WRes ManualResetEvent_Create(CManualResetEvent *p, int signaled)
{ return Event_Create(p, True, signaled); }
WRes ManualResetEvent_CreateNotSignaled(CManualResetEvent *p)
{ return ManualResetEvent_Create(p, 0); }
WRes AutoResetEvent_Create(CAutoResetEvent *p, int signaled)
{ return Event_Create(p, False, signaled); }
WRes AutoResetEvent_CreateNotSignaled(CAutoResetEvent *p)
{ return AutoResetEvent_Create(p, 0); }
WRes Event_Set(CEvent *p)
{
RINOK(pthread_mutex_lock(&p->_mutex));
p->_state = True;
int res1 = pthread_cond_broadcast(&p->_cond);
int res2 = pthread_mutex_unlock(&p->_mutex);
return (res2 ? res2 : res1);
}
WRes Event_Reset(CEvent *p)
{
RINOK(pthread_mutex_lock(&p->_mutex));
p->_state = False;
return pthread_mutex_unlock(&p->_mutex);
}
WRes Event_Wait(CEvent *p)
{
RINOK(pthread_mutex_lock(&p->_mutex));
while (p->_state == False)
{
// ETIMEDOUT
// ret =
pthread_cond_wait(&p->_cond, &p->_mutex);
// if (ret != 0) break;
}
if (p->_manual_reset == False)
{
p->_state = False;
}
return pthread_mutex_unlock(&p->_mutex);
}
WRes Event_Close(CEvent *p)
{
if (!p->_created)
return 0;
p->_created = 0;
{
int res1 = pthread_mutex_destroy(&p->_mutex);
int res2 = pthread_cond_destroy(&p->_cond);
return (res1 ? res1 : res2);
}
}
WRes Semaphore_Create(CSemaphore *p, UInt32 initCount, UInt32 maxCount)
{
if (initCount > maxCount || maxCount < 1)
return EINVAL;
RINOK(pthread_mutex_init(&p->_mutex, NULL));
RINOK(pthread_cond_init(&p->_cond, NULL));
p->_count = initCount;
p->_maxCount = maxCount;
p->_created = 1;
return 0;
}
WRes Semaphore_OptCreateInit(CSemaphore *p, UInt32 initCount, UInt32 maxCount)
{
if (Semaphore_IsCreated(p))
{
/*
WRes wres = Semaphore_Close(p);
if (wres != 0)
return wres;
*/
if (initCount > maxCount || maxCount < 1)
return EINVAL;
// return EINVAL; // for debug
p->_count = initCount;
p->_maxCount = maxCount;
return 0;
}
return Semaphore_Create(p, initCount, maxCount);
}
WRes Semaphore_ReleaseN(CSemaphore *p, UInt32 releaseCount)
{
UInt32 newCount;
int ret;
if (releaseCount < 1)
return EINVAL;
RINOK(pthread_mutex_lock(&p->_mutex));
newCount = p->_count + releaseCount;
if (newCount > p->_maxCount)
ret = ERROR_TOO_MANY_POSTS; // EINVAL;
else
{
p->_count = newCount;
ret = pthread_cond_broadcast(&p->_cond);
}
RINOK(pthread_mutex_unlock(&p->_mutex));
return ret;
}
WRes Semaphore_Wait(CSemaphore *p)
{
RINOK(pthread_mutex_lock(&p->_mutex));
while (p->_count < 1)
{
pthread_cond_wait(&p->_cond, &p->_mutex);
}
p->_count--;
return pthread_mutex_unlock(&p->_mutex);
}
WRes Semaphore_Close(CSemaphore *p)
{
if (!p->_created)
return 0;
p->_created = 0;
{
int res1 = pthread_mutex_destroy(&p->_mutex);
int res2 = pthread_cond_destroy(&p->_cond);
return (res1 ? res1 : res2);
}
}
WRes CriticalSection_Init(CCriticalSection *p)
{
// Print("CriticalSection_Init");
if (!p)
return EINTR;
return pthread_mutex_init(&p->_mutex, NULL);
}
void CriticalSection_Enter(CCriticalSection *p)
{
// Print("CriticalSection_Enter");
if (p)
{
// int ret =
pthread_mutex_lock(&p->_mutex);
}
}
void CriticalSection_Leave(CCriticalSection *p)
{
// Print("CriticalSection_Leave");
if (p)
{
// int ret =
pthread_mutex_unlock(&p->_mutex);
}
}
void CriticalSection_Delete(CCriticalSection *p)
{
// Print("CriticalSection_Delete");
if (p)
{
// int ret =
pthread_mutex_destroy(&p->_mutex);
}
}
LONG InterlockedIncrement(LONG volatile *addend)
{
// Print("InterlockedIncrement");
#ifdef USE_HACK_UNSAFE_ATOMIC
LONG val = *addend + 1;
*addend = val;
return val;
#else
return __sync_add_and_fetch(addend, 1);
#endif
}
#endif // _WIN32