• pthread 库重要的头文件


    #ifndef _IMPLEMENT_H
    #define _IMPLEMENT_H
    
    #ifdef _WIN32_WINNT
    #undef _WIN32_WINNT
    #endif
    #define _WIN32_WINNT 0x400
    
    #include <windows.h>
    
    /*
     * In case windows.h doesn't define it (e.g. WinCE perhaps)
     */
    #ifdef WINCE
    typedef VOID (APIENTRY *PAPCFUNC)(DWORD dwParam);
    #endif
    
    /*
     * note: ETIMEDOUT is correctly defined in winsock.h
     */
    #include <winsock.h>
    
    /*
     * In case ETIMEDOUT hasn't been defined above somehow.
     */
    #ifndef ETIMEDOUT
    #  define ETIMEDOUT 10060    /* This is the value in winsock.h. */
    #endif
    
    #if !defined(malloc)
    #include <malloc.h>
    #endif
    
    #if !defined(INT_MAX)
    #include <limits.h>
    #endif
    
    /* use local include files during development */
    #include "semaphore.h"
    #include "sched.h"
    
    #if defined(HAVE_C_INLINE) || defined(__cplusplus)
    #define INLINE inline
    #else
    #define INLINE
    #endif
    
    #if defined (__MINGW32__) || (_MSC_VER >= 1300)
    #define PTW32_INTERLOCKED_LONG long
    #define PTW32_INTERLOCKED_LPLONG long*
    #else
    #define PTW32_INTERLOCKED_LONG PVOID
    #define PTW32_INTERLOCKED_LPLONG PVOID*
    #endif
    
    #if defined(__MINGW32__)
    #include <stdint.h>
    #elif defined(__BORLANDC__)
    #define int64_t ULONGLONG
    #else
    #define int64_t _int64
    #endif
    
    typedef enum
    {
      /*
       * This enumeration represents the state of the thread;
       * The thread is still "alive" if the numeric value of the
       * state is greater or equal "PThreadStateRunning".
       */
      PThreadStateInitial = 0,    /* Thread not running                   */
      PThreadStateRunning,        /* Thread alive & kicking               */
      PThreadStateSuspended,    /* Thread alive but suspended           */
      PThreadStateCancelPending,    /* Thread alive but is                  */
      /* has cancelation pending.        */
      PThreadStateCanceling,    /* Thread alive but is                  */
      /* in the process of terminating        */
      /* due to a cancellation request        */
      PThreadStateException,    /* Thread alive but exiting             */
      /* due to an exception                  */
      PThreadStateLast
    }
    PThreadState;
    
    
    typedef struct ptw32_thread_t_ ptw32_thread_t;
    
    struct ptw32_thread_t_
    {
    #ifdef _UWIN
      DWORD dummy[5];
    #endif
      DWORD thread;
      HANDLE threadH;        /* Win32 thread handle - POSIX thread is invalid if threadH == 0 */
      pthread_t ptHandle;        /* This thread's permanent pthread_t handle */
      ptw32_thread_t * prevReuse;    /* Links threads on reuse stack */
      volatile PThreadState state;
      void *exitStatus;
      void *parms;
      int ptErrno;
      int detachState;
      pthread_mutex_t threadLock;    /* Used for serialised access to public thread state */
      int sched_priority;        /* As set, not as currently is */
      pthread_mutex_t cancelLock;    /* Used for async-cancel safety */
      int cancelState;
      int cancelType;
      HANDLE cancelEvent;
    #ifdef __CLEANUP_C
      jmp_buf start_mark;
    #endif                /* __CLEANUP_C */
    #if HAVE_SIGSET_T
      sigset_t sigmask;
    #endif                /* HAVE_SIGSET_T */
      int implicit:1;
      void *keys;
      void *nextAssoc;
    };
    
    
    /* 
     * Special value to mark attribute objects as valid.
     */
    #define PTW32_ATTR_VALID ((unsigned long) 0xC4C0FFEE)
    
    struct pthread_attr_t_
    {
      unsigned long valid;
      void *stackaddr;
      size_t stacksize;
      int detachstate;
      struct sched_param param;
      int inheritsched;
      int contentionscope;
    #if HAVE_SIGSET_T
      sigset_t sigmask;
    #endif                /* HAVE_SIGSET_T */
    };
    
    
    /*
     * ====================
     * ====================
     * Semaphores, Mutexes and Condition Variables
     * ====================
     * ====================
     */
    
    struct sem_t_
    {
      int value;
      pthread_mutex_t lock;
      HANDLE sem;
    #ifdef NEED_SEM
      int leftToUnblock;
    #endif
    };
    
    #define PTW32_OBJECT_AUTO_INIT ((void *) -1)
    #define PTW32_OBJECT_INVALID   NULL
    
    struct pthread_mutex_t_
    {
      LONG lock_idx;        /* Provides exclusive access to mutex state
                       via the Interlocked* mechanism.
                        0: unlocked/free.
                        1: locked - no other waiters.
                       -1: locked - with possible other waiters.
                    */
      int recursive_count;        /* Number of unlocks a thread needs to perform
                       before the lock is released (recursive
                       mutexes only). */
      int kind;            /* Mutex type. */
      pthread_t ownerThread;
      HANDLE event;            /* Mutex release notification to waiting
                       threads. */
    };
    
    struct pthread_mutexattr_t_
    {
      int pshared;
      int kind;
    };
    
    /*
     * Possible values, other than PTW32_OBJECT_INVALID,
     * for the "interlock" element in a spinlock.
     *
     * In this implementation, when a spinlock is initialised,
     * the number of cpus available to the process is checked.
     * If there is only one cpu then "interlock" is set equal to
     * PTW32_SPIN_USE_MUTEX and u.mutex is a initialised mutex.
     * If the number of cpus is greater than 1 then "interlock"
     * is set equal to PTW32_SPIN_UNLOCKED and the number is
     * stored in u.cpus. This arrangement allows the spinlock
     * routines to attempt an InterlockedCompareExchange on "interlock"
     * immediately and, if that fails, to try the inferior mutex.
     *
     * "u.cpus" isn't used for anything yet, but could be used at
     * some point to optimise spinlock behaviour.
     */
    #define PTW32_SPIN_UNLOCKED    (1)
    #define PTW32_SPIN_LOCKED      (2)
    #define PTW32_SPIN_USE_MUTEX   (3)
    
    struct pthread_spinlock_t_
    {
      long interlock;        /* Locking element for multi-cpus. */
      union
      {
        int cpus;            /* No. of cpus if multi cpus, or   */
        pthread_mutex_t mutex;    /* mutex if single cpu.            */
      } u;
    };
    
    struct pthread_barrier_t_
    {
      unsigned int nCurrentBarrierHeight;
      unsigned int nInitialBarrierHeight;
      int iStep;
      int pshared;
      sem_t semBarrierBreeched[2];
    };
    
    struct pthread_barrierattr_t_
    {
      int pshared;
    };
    
    struct pthread_key_t_
    {
      DWORD key;
      void (*destructor) (void *);
      pthread_mutex_t keyLock;
      void *threads;
    };
    
    
    typedef struct ThreadParms ThreadParms;
    typedef struct ThreadKeyAssoc ThreadKeyAssoc;
    
    struct ThreadParms
    {
      pthread_t tid;
      void *(*start) (void *);
      void *arg;
    };
    
    
    struct pthread_cond_t_
    {
      long nWaitersBlocked;        /* Number of threads blocked            */
      long nWaitersGone;        /* Number of threads timed out          */
      long nWaitersToUnblock;    /* Number of threads to unblock         */
      sem_t semBlockQueue;        /* Queue up threads waiting for the     */
      /*   condition to become signalled      */
      sem_t semBlockLock;        /* Semaphore that guards access to      */
      /* | waiters blocked count/block queue  */
      /* +-> Mandatory Sync.LEVEL-1           */
      pthread_mutex_t mtxUnblockLock;    /* Mutex that guards access to          */
      /* | waiters (to)unblock(ed) counts     */
      /* +-> Optional* Sync.LEVEL-2           */
      pthread_cond_t next;        /* Doubly linked list                   */
      pthread_cond_t prev;
    };
    
    
    struct pthread_condattr_t_
    {
      int pshared;
    };
    
    #define PTW32_RWLOCK_MAGIC 0xfacade2
    
    struct pthread_rwlock_t_
    {
      pthread_mutex_t mtxExclusiveAccess;
      pthread_mutex_t mtxSharedAccessCompleted;
      pthread_cond_t cndSharedAccessCompleted;
      int nSharedAccessCount;
      int nExclusiveAccessCount;
      int nCompletedSharedAccessCount;
      int nMagic;
    };
    
    struct pthread_rwlockattr_t_
    {
      int pshared;
    };
    
    /*
     * MCS lock queue node - see ptw32_MCS_lock.c
     */
    struct ptw32_mcs_node_t_
    {
      struct ptw32_mcs_node_t_ **lock;        /* ptr to tail of queue */
      struct ptw32_mcs_node_t_  *next;        /* ptr to successor in queue */
      LONG                       readyFlag;   /* set after lock is released by
                                                 predecessor */
      LONG                       nextFlag;    /* set after 'next' ptr is set by
                                                 successor */
    };
    
    typedef struct ptw32_mcs_node_t_   ptw32_mcs_local_node_t;
    typedef struct ptw32_mcs_node_t_  *ptw32_mcs_lock_t;
    
    
    struct ThreadKeyAssoc
    {
      /*
       * Purpose:
       *      This structure creates an association between a thread and a key.
       *      It is used to implement the implicit invocation of a user defined
       *      destroy routine for thread specific data registered by a user upon
       *      exiting a thread.
       *
       *      Graphically, the arrangement is as follows, where:
       *
       *         K - Key with destructor
       *            (head of chain is key->threads)
       *         T - Thread that has called pthread_setspecific(Kn)
       *            (head of chain is thread->keys)
       *         A - Association. Each association is a node at the
       *             intersection of two doubly-linked lists.
       *
       *                 T1    T2    T3
       *                 |     |     |
       *                 |     |     |
       *         K1 -----+-----A-----A----->
       *                 |     |     |
       *                 |     |     |
       *         K2 -----A-----A-----+----->
       *                 |     |     |
       *                 |     |     |
       *         K3 -----A-----+-----A----->
       *                 |     |     |
       *                 |     |     |
       *                 V     V     V
       *
       *      Access to the association is guarded by two locks: the key's
       *      general lock (guarding the row) and the thread's general
       *      lock (guarding the column). This avoids the need for a
       *      dedicated lock for each association, which not only consumes
       *      more handles but requires that: before the lock handle can
       *      be released - both the key must be deleted and the thread
       *      must have called the destructor. The two-lock arrangement
       *      allows the resources to be freed as soon as either thread or
       *      key is concluded.
       *
       *      To avoid deadlock: whenever both locks are required, the key
       *      and thread locks are always acquired in the order: key lock
       *      then thread lock. An exception to this exists when a thread
       *      calls the destructors, however this is done carefully to
       *      avoid deadlock.
       *
       *      An association is created when a thread first calls
       *      pthread_setspecific() on a key that has a specified
       *      destructor.
       *
       *      An association is destroyed either immediately after the
       *      thread calls the key destructor function on thread exit, or
       *      when the key is deleted.
       *
       * Attributes:
       *      thread
       *              reference to the thread that owns the
       *              association. This is actually the pointer to the
       *              thread struct itself. Since the association is
       *              destroyed before the thread exits, this can never
       *              point to a different logical thread to the one that
       *              created the assoc, i.e. after thread struct reuse.
       *
       *      key
       *              reference to the key that owns the association.
       *
       *      nextKey
       *              The pthread_t->keys attribute is the head of a
       *              chain of associations that runs through the nextKey
       *              link. This chain provides the 1 to many relationship
       *              between a pthread_t and all pthread_key_t on which
       *              it called pthread_setspecific.
       *
       *      prevKey
       *              Similarly.
       *
       *      nextThread
       *              The pthread_key_t->threads attribute is the head of
       *              a chain of assoctiations that runs through the
       *              nextThreads link. This chain provides the 1 to many
       *              relationship between a pthread_key_t and all the 
       *              PThreads that have called pthread_setspecific for
       *              this pthread_key_t.
       *
       *      prevThread
       *              Similarly.
       *
       * Notes:
       *      1)      As soon as either the key or the thread is no longer
       *              referencing the association, it can be destroyed. The
       *              association will be removed from both chains.
       *
       *      2)      Under WIN32, an association is only created by
       *              pthread_setspecific if the user provided a
       *              destroyRoutine when they created the key.
       *
       *
       */
      ptw32_thread_t * thread;
      pthread_key_t key;
      ThreadKeyAssoc *nextKey;
      ThreadKeyAssoc *nextThread;
      ThreadKeyAssoc *prevKey;
      ThreadKeyAssoc *prevThread;
    };
    
    
    #ifdef __CLEANUP_SEH
    /*
     * --------------------------------------------------------------
     * MAKE_SOFTWARE_EXCEPTION
     *      This macro constructs a software exception code following
     *      the same format as the standard Win32 error codes as defined
     *      in WINERROR.H
     *  Values are 32 bit values layed out as follows:
     *
     *   1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
     *  +---+-+-+-----------------------+-------------------------------+
     *  |Sev|C|R|     Facility          |               Code            |
     *  +---+-+-+-----------------------+-------------------------------+
     *
     * Severity Values:
     */
    #define SE_SUCCESS              0x00
    #define SE_INFORMATION          0x01
    #define SE_WARNING              0x02
    #define SE_ERROR                0x03
    
    #define MAKE_SOFTWARE_EXCEPTION( _severity, _facility, _exception ) 
    ( (DWORD) ( ( (_severity) << 30 ) |     /* Severity code        */ 
                ( 1 << 29 ) |               /* MS=0, User=1         */ 
                ( 0 << 28 ) |               /* Reserved             */ 
                ( (_facility) << 16 ) |     /* Facility Code        */ 
                ( (_exception) <<  0 )      /* Exception Code       */ 
                ) )
    
    /*
     * We choose one specific Facility/Error code combination to
     * identify our software exceptions vs. WIN32 exceptions.
     * We store our actual component and error code within
     * the optional information array.
     */
    #define EXCEPTION_PTW32_SERVICES        
         MAKE_SOFTWARE_EXCEPTION( SE_ERROR, 
                                  PTW32_SERVICES_FACILITY, 
                                  PTW32_SERVICES_ERROR )
    
    #define PTW32_SERVICES_FACILITY         0xBAD
    #define PTW32_SERVICES_ERROR            0xDEED
    
    #endif /* __CLEANUP_SEH */
    
    /*
     * Services available through EXCEPTION_PTW32_SERVICES
     * and also used [as parameters to ptw32_throw()] as
     * generic exception selectors.
     */
    
    #define PTW32_EPS_EXIT                  (1)
    #define PTW32_EPS_CANCEL                (2)
    
    
    /* Useful macros */
    #define PTW32_MAX(a,b)  ((a)<(b)?(b):(a))
    #define PTW32_MIN(a,b)  ((a)>(b)?(b):(a))
    
    
    /* Declared in global.c */
    extern PTW32_INTERLOCKED_LONG (WINAPI *
                       ptw32_interlocked_compare_exchange)
      (PTW32_INTERLOCKED_LPLONG, PTW32_INTERLOCKED_LONG, PTW32_INTERLOCKED_LONG);
    
    /* Declared in pthread_cancel.c */
    extern DWORD (*ptw32_register_cancelation) (PAPCFUNC, HANDLE, DWORD);
    
    /* Thread Reuse stack bottom marker. Must not be NULL or any valid pointer to memory. */
    #define PTW32_THREAD_REUSE_EMPTY ((ptw32_thread_t *) 1)
    
    extern int ptw32_processInitialized;
    extern ptw32_thread_t * ptw32_threadReuseTop;
    extern ptw32_thread_t * ptw32_threadReuseBottom;
    extern pthread_key_t ptw32_selfThreadKey;
    extern pthread_key_t ptw32_cleanupKey;
    extern pthread_cond_t ptw32_cond_list_head;
    extern pthread_cond_t ptw32_cond_list_tail;
    
    extern int ptw32_mutex_default_kind;
    
    extern int ptw32_concurrency;
    
    extern int ptw32_features;
    
    extern BOOL ptw32_smp_system;  /* True: SMP system, False: Uni-processor system */
    
    extern CRITICAL_SECTION ptw32_thread_reuse_lock;
    extern CRITICAL_SECTION ptw32_mutex_test_init_lock;
    extern CRITICAL_SECTION ptw32_cond_list_lock;
    extern CRITICAL_SECTION ptw32_cond_test_init_lock;
    extern CRITICAL_SECTION ptw32_rwlock_test_init_lock;
    extern CRITICAL_SECTION ptw32_spinlock_test_init_lock;
    
    #ifdef _UWIN
    extern int pthread_count;
    #endif
    
    #ifdef __cplusplus
    extern "C"
    {
    #endif                /* __cplusplus */
    
    /*
     * =====================
     * =====================
     * Forward Declarations
     * =====================
     * =====================
     */
    
      int ptw32_is_attr (const pthread_attr_t * attr);
    
      int ptw32_cond_check_need_init (pthread_cond_t * cond);
      int ptw32_mutex_check_need_init (pthread_mutex_t * mutex);
      int ptw32_rwlock_check_need_init (pthread_rwlock_t * rwlock);
    
      PTW32_INTERLOCKED_LONG WINAPI
        ptw32_InterlockedCompareExchange (PTW32_INTERLOCKED_LPLONG location,
                          PTW32_INTERLOCKED_LONG value,
                          PTW32_INTERLOCKED_LONG comparand);
    
      LONG WINAPI
        ptw32_InterlockedExchange (LPLONG location,
                       LONG value);
    
      DWORD
        ptw32_RegisterCancelation (PAPCFUNC callback,
                       HANDLE threadH, DWORD callback_arg);
    
      int ptw32_processInitialize (void);
    
      void ptw32_processTerminate (void);
    
      void ptw32_threadDestroy (pthread_t tid);
    
      void ptw32_pop_cleanup_all (int execute);
    
      pthread_t ptw32_new (void);
    
      pthread_t ptw32_threadReusePop (void);
    
      void ptw32_threadReusePush (pthread_t thread);
    
      int ptw32_getprocessors (int *count);
    
      int ptw32_setthreadpriority (pthread_t thread, int policy, int priority);
    
      void ptw32_rwlock_cancelwrwait (void *arg);
    
    #if ! defined (__MINGW32__) || defined (__MSVCRT__)
      unsigned __stdcall
    #else
      void
    #endif
        ptw32_threadStart (void *vthreadParms);
    
      void ptw32_callUserDestroyRoutines (pthread_t thread);
    
      int ptw32_tkAssocCreate (ptw32_thread_t * thread, pthread_key_t key);
    
      void ptw32_tkAssocDestroy (ThreadKeyAssoc * assoc);
    
      int ptw32_semwait (sem_t * sem);
    
      DWORD ptw32_relmillisecs (const struct timespec * abstime);
    
      void ptw32_mcs_lock_acquire (ptw32_mcs_lock_t * lock, ptw32_mcs_local_node_t * node);
    
      void ptw32_mcs_lock_release (ptw32_mcs_local_node_t * node);
    
    #ifdef NEED_FTIME
      void ptw32_timespec_to_filetime (const struct timespec *ts, FILETIME * ft);
      void ptw32_filetime_to_timespec (const FILETIME * ft, struct timespec *ts);
    #endif
    
    /* Declared in misc.c */
    #ifdef NEED_CALLOC
    #define calloc(n, s) ptw32_calloc(n, s)
      void *ptw32_calloc (size_t n, size_t s);
    #endif
    
    /* Declared in private.c */
      void ptw32_throw (DWORD exception);
    
    #ifdef __cplusplus
    }
    #endif                /* __cplusplus */
    
    
    #ifdef _UWIN_
    #   ifdef       _MT
    #       ifdef __cplusplus
    extern "C"
    {
    #       endif
      _CRTIMP unsigned long __cdecl _beginthread (void (__cdecl *) (void *),
                              unsigned, void *);
      _CRTIMP void __cdecl _endthread (void);
      _CRTIMP unsigned long __cdecl _beginthreadex (void *, unsigned,
                            unsigned (__stdcall *) (void *),
                            void *, unsigned, unsigned *);
      _CRTIMP void __cdecl _endthreadex (unsigned);
    #       ifdef __cplusplus
    }
    #       endif
    #   endif
    #else
    #   include <process.h>
    #endif
    
    
    /*
     * Defaults. Could be overridden when building the inlined version of the dll.
     * See ptw32_InterlockedCompareExchange.c
     */
    #ifndef PTW32_INTERLOCKED_COMPARE_EXCHANGE
    #define PTW32_INTERLOCKED_COMPARE_EXCHANGE ptw32_interlocked_compare_exchange
    #endif
    
    #ifndef PTW32_INTERLOCKED_EXCHANGE
    #define PTW32_INTERLOCKED_EXCHANGE InterlockedExchange
    #endif
    
    
    /*
     * Check for old and new versions of cygwin. See the FAQ file:
     *
     * Question 1 - How do I get pthreads-win32 to link under Cygwin or Mingw32?
     *
     * Patch by Anders Norlander <anorland@hem2.passagen.se>
     */
    #if defined(__CYGWIN32__) || defined(__CYGWIN__) || defined(NEED_CREATETHREAD)
    
    /* 
     * Macro uses args so we can cast start_proc to LPTHREAD_START_ROUTINE
     * in order to avoid warnings because of return type
     */
    
    #define _beginthreadex(security, 
                           stack_size, 
                           start_proc, 
                           arg, 
                           flags, 
                           pid) 
            CreateThread(security, 
                         stack_size, 
                         (LPTHREAD_START_ROUTINE) start_proc, 
                         arg, 
                         flags, 
                         pid)
    
    #define _endthreadex ExitThread
    
    #endif                /* __CYGWIN32__ || __CYGWIN__ || NEED_CREATETHREAD */
    
    
    #endif                /* _IMPLEMENT_H */
    一勤天下无难事。
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  • 原文地址:https://www.cnblogs.com/nowroot/p/12635885.html
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