PR java/10145

[official-gcc.git] / boehm-gc / win32_threads.c

#if defined(GC_WIN32_THREADS)

#include "private/gc_priv.h"

#if 0
#define STRICT
#include <windows.h>
#endif

#define MAX_THREADS 64

struct thread_entry {
  LONG in_use;
  DWORD id;
  HANDLE handle;
  void *stack;          /* The cold end of the stack.   */
                        /* 0 ==> entry not valid.       */
                        /* !in_use ==> stack == 0       */
  CONTEXT context;
  GC_bool suspended;
};

volatile GC_bool GC_please_stop = FALSE;

volatile struct thread_entry thread_table[MAX_THREADS];

void GC_push_thread_structures GC_PROTO((void))
{
    /* Unlike the other threads implementations, the thread table here  */
    /* contains no pointers to the collectable heap.  Thus we have      */
    /* no private structures we need to preserve.                       */
}

void GC_stop_world()
{
  DWORD thread_id = GetCurrentThreadId();
  int i;

  GC_please_stop = TRUE;
  for (i = 0; i < MAX_THREADS; i++)
    if (thread_table[i].stack != 0
        && thread_table[i].id != thread_id) {
#     ifdef MSWINCE
        /* SuspendThread will fail if thread is running kernel code */
        while (SuspendThread(thread_table[i].handle) == (DWORD)-1)
          Sleep(10);
#     else
        /* Apparently the Windows 95 GetOpenFileName call creates       */
        /* a thread that does not properly get cleaned up, and          */
        /* SuspendThread on its descriptor may provoke a crash.         */
        /* This reduces the probability of that event, though it still  */
        /* appears there's a race here.                                 */
        DWORD exitCode; 
        if (GetExitCodeThread(thread_table[i].handle,&exitCode) &&
            exitCode != STILL_ACTIVE) {
            thread_table[i].stack = 0;
            thread_table[i].in_use = FALSE;
            CloseHandle(thread_table[i].handle);
            BZERO((void *)(&thread_table[i].context), sizeof(CONTEXT));
            continue;
        }
        if (SuspendThread(thread_table[i].handle) == (DWORD)-1)
          ABORT("SuspendThread failed");
#     endif
      thread_table[i].suspended = TRUE;
    }
}

void GC_start_world()
{
  DWORD thread_id = GetCurrentThreadId();
  int i;
  for (i = 0; i < MAX_THREADS; i++)
    if (thread_table[i].stack != 0 && thread_table[i].suspended
        && thread_table[i].id != thread_id) {
      if (ResumeThread(thread_table[i].handle) == (DWORD)-1)
        ABORT("ResumeThread failed");
      thread_table[i].suspended = FALSE;
    }
  GC_please_stop = FALSE;
}

# ifdef _MSC_VER
#   pragma warning(disable:4715)
# endif
ptr_t GC_current_stackbottom()
{
  DWORD thread_id = GetCurrentThreadId();
  int i;
  for (i = 0; i < MAX_THREADS; i++)
    if (thread_table[i].stack && thread_table[i].id == thread_id)
      return thread_table[i].stack;
  ABORT("no thread table entry for current thread");
}
# ifdef _MSC_VER
#   pragma warning(default:4715)
# endif

# ifdef MSWINCE
    /* The VirtualQuery calls below won't work properly on WinCE, but   */
    /* since each stack is restricted to an aligned 64K region of       */
    /* virtual memory we can just take the next lowest multiple of 64K. */
#   define GC_get_lo_stack_addr(s) \
        ((ptr_t)(((DWORD)(s) - 1) & 0xFFFF0000))
# else
    static ptr_t GC_get_lo_stack_addr(ptr_t s)
    {
        ptr_t bottom;
        MEMORY_BASIC_INFORMATION info;
        VirtualQuery(s, &info, sizeof(info));
        do {
            bottom = info.BaseAddress;
            VirtualQuery(bottom - 1, &info, sizeof(info));
        } while ((info.Protect & PAGE_READWRITE)
                 && !(info.Protect & PAGE_GUARD));
        return(bottom);
    }
# endif

void GC_push_all_stacks()
{
  DWORD thread_id = GetCurrentThreadId();
  int i;
  for (i = 0; i < MAX_THREADS; i++)
    if (thread_table[i].stack) {
      ptr_t bottom = GC_get_lo_stack_addr(thread_table[i].stack);
      if (thread_table[i].id == thread_id)
        GC_push_all_stack((ptr_t)&i, thread_table[i].stack);
      else {
        thread_table[i].context.ContextFlags
                        = (CONTEXT_INTEGER|CONTEXT_CONTROL);
        if (!GetThreadContext(thread_table[i].handle,
                                /* cast away volatile qualifier */
                                (LPCONTEXT)&thread_table[i].context))
          ABORT("GetThreadContext failed");
#       ifdef I386
          GC_push_one ((word) thread_table[i].context.Edi);
          GC_push_one ((word) thread_table[i].context.Esi);
          GC_push_one ((word) thread_table[i].context.Ebp);
          GC_push_one ((word) thread_table[i].context.Ebx);
          GC_push_one ((word) thread_table[i].context.Edx);
          GC_push_one ((word) thread_table[i].context.Ecx);
          GC_push_one ((word) thread_table[i].context.Eax);
          if (thread_table[i].context.Esp >= (DWORD)thread_table[i].stack
              || thread_table[i].context.Esp < (DWORD)bottom) {
              WARN("Thread stack pointer 0x%lx out of range, pushing everything",
                   thread_table[i].context.Esp);
              GC_push_all_stack((char *) bottom, thread_table[i].stack);
          } else {
              GC_push_all_stack((char *) thread_table[i].context.Esp,
                                thread_table[i].stack);
          }
#       else
#       ifdef ARM32
          if (thread_table[i].context.Sp >= (DWORD)thread_table[i].stack
              || thread_table[i].context.Sp < (DWORD)bottom)
              ABORT("Thread stack pointer out of range");
          GC_push_one ((word) thread_table[i].context.R0);
          GC_push_one ((word) thread_table[i].context.R1);
          GC_push_one ((word) thread_table[i].context.R2);
          GC_push_one ((word) thread_table[i].context.R3);
          GC_push_one ((word) thread_table[i].context.R4);
          GC_push_one ((word) thread_table[i].context.R5);
          GC_push_one ((word) thread_table[i].context.R6);
          GC_push_one ((word) thread_table[i].context.R7);
          GC_push_one ((word) thread_table[i].context.R8);
          GC_push_one ((word) thread_table[i].context.R9);
          GC_push_one ((word) thread_table[i].context.R10);
          GC_push_one ((word) thread_table[i].context.R11);
          GC_push_one ((word) thread_table[i].context.R12);
          GC_push_all_stack((char *) thread_table[i].context.Sp,
                            thread_table[i].stack);
#       else
#       ifdef SHx
          if (thread_table[i].context.R15 >= (DWORD)thread_table[i].stack
              || thread_table[i].context.R15 < (DWORD)bottom)
              ABORT("Thread stack pointer out of range");
          GC_push_one ((word) thread_table[i].context.R0);
          GC_push_one ((word) thread_table[i].context.R1);
          GC_push_one ((word) thread_table[i].context.R2);
          GC_push_one ((word) thread_table[i].context.R3);
          GC_push_one ((word) thread_table[i].context.R4);
          GC_push_one ((word) thread_table[i].context.R5);
          GC_push_one ((word) thread_table[i].context.R6);
          GC_push_one ((word) thread_table[i].context.R7);
          GC_push_one ((word) thread_table[i].context.R8);
          GC_push_one ((word) thread_table[i].context.R9);
          GC_push_one ((word) thread_table[i].context.R10);
          GC_push_one ((word) thread_table[i].context.R11);
          GC_push_one ((word) thread_table[i].context.R12);
          GC_push_one ((word) thread_table[i].context.R13);
          GC_push_one ((word) thread_table[i].context.R14);
          GC_push_all_stack((char *) thread_table[i].context.R15,
                            thread_table[i].stack);
#       else
#       ifdef MIPS
          if (thread_table[i].context.IntSp >= (DWORD)thread_table[i].stack
              || thread_table[i].context.IntSp < (DWORD)bottom)
              ABORT("Thread stack pointer out of range");
          GC_push_one ((word) thread_table[i].context.IntAt);
          GC_push_one ((word) thread_table[i].context.IntV0);
          GC_push_one ((word) thread_table[i].context.IntV1);
          GC_push_one ((word) thread_table[i].context.IntA0);
          GC_push_one ((word) thread_table[i].context.IntA1);
          GC_push_one ((word) thread_table[i].context.IntA2);
          GC_push_one ((word) thread_table[i].context.IntA3);
          GC_push_one ((word) thread_table[i].context.IntT0);
          GC_push_one ((word) thread_table[i].context.IntT1);
          GC_push_one ((word) thread_table[i].context.IntT2);
          GC_push_one ((word) thread_table[i].context.IntT3);
          GC_push_one ((word) thread_table[i].context.IntT4);
          GC_push_one ((word) thread_table[i].context.IntT5);
          GC_push_one ((word) thread_table[i].context.IntT6);
          GC_push_one ((word) thread_table[i].context.IntT7);
          GC_push_one ((word) thread_table[i].context.IntS0);
          GC_push_one ((word) thread_table[i].context.IntS1);
          GC_push_one ((word) thread_table[i].context.IntS2);
          GC_push_one ((word) thread_table[i].context.IntS3);
          GC_push_one ((word) thread_table[i].context.IntS4);
          GC_push_one ((word) thread_table[i].context.IntS5);
          GC_push_one ((word) thread_table[i].context.IntS6);
          GC_push_one ((word) thread_table[i].context.IntS7);
          GC_push_one ((word) thread_table[i].context.IntT8);
          GC_push_one ((word) thread_table[i].context.IntT9);
          GC_push_one ((word) thread_table[i].context.IntK0);
          GC_push_one ((word) thread_table[i].context.IntK1);
          GC_push_one ((word) thread_table[i].context.IntS8);
          GC_push_all_stack((char *) thread_table[i].context.IntSp,
                            thread_table[i].stack);
#       else
#       ifdef PPC
          if (thread_table[i].context.Gpr1 >= (DWORD)thread_table[i].stack
              || thread_table[i].context.Gpr1 < (DWORD)bottom)
              ABORT("Thread stack pointer out of range");
          GC_push_one ((word) thread_table[i].context.Gpr0);
          /* Gpr1 is stack pointer */
          /* Gpr2 is global pointer */
          GC_push_one ((word) thread_table[i].context.Gpr3);
          GC_push_one ((word) thread_table[i].context.Gpr4);
          GC_push_one ((word) thread_table[i].context.Gpr5);
          GC_push_one ((word) thread_table[i].context.Gpr6);
          GC_push_one ((word) thread_table[i].context.Gpr7);
          GC_push_one ((word) thread_table[i].context.Gpr8);
          GC_push_one ((word) thread_table[i].context.Gpr9);
          GC_push_one ((word) thread_table[i].context.Gpr10);
          GC_push_one ((word) thread_table[i].context.Gpr11);
          GC_push_one ((word) thread_table[i].context.Gpr12);
          /* Gpr13 is reserved for the kernel */
          GC_push_one ((word) thread_table[i].context.Gpr14);
          GC_push_one ((word) thread_table[i].context.Gpr15);
          GC_push_one ((word) thread_table[i].context.Gpr16);
          GC_push_one ((word) thread_table[i].context.Gpr17);
          GC_push_one ((word) thread_table[i].context.Gpr18);
          GC_push_one ((word) thread_table[i].context.Gpr19);
          GC_push_one ((word) thread_table[i].context.Gpr20);
          GC_push_one ((word) thread_table[i].context.Gpr21);
          GC_push_one ((word) thread_table[i].context.Gpr22);
          GC_push_one ((word) thread_table[i].context.Gpr23);
          GC_push_one ((word) thread_table[i].context.Gpr24);
          GC_push_one ((word) thread_table[i].context.Gpr25);
          GC_push_one ((word) thread_table[i].context.Gpr26);
          GC_push_one ((word) thread_table[i].context.Gpr27);
          GC_push_one ((word) thread_table[i].context.Gpr28);
          GC_push_one ((word) thread_table[i].context.Gpr29);
          GC_push_one ((word) thread_table[i].context.Gpr30);
          GC_push_one ((word) thread_table[i].context.Gpr31);
          GC_push_all_stack((char *) thread_table[i].context.Gpr1,
                            thread_table[i].stack);
#       else
#       ifdef ALPHA
          if (thread_table[i].context.IntSp >= (DWORD)thread_table[i].stack
              || thread_table[i].context.IntSp < (DWORD)bottom)
              ABORT("Thread stack pointer out of range");
          GC_push_one ((word) thread_table[i].context.IntV0);
          GC_push_one ((word) thread_table[i].context.IntT0);
          GC_push_one ((word) thread_table[i].context.IntT1);
          GC_push_one ((word) thread_table[i].context.IntT2);
          GC_push_one ((word) thread_table[i].context.IntT3);
          GC_push_one ((word) thread_table[i].context.IntT4);
          GC_push_one ((word) thread_table[i].context.IntT5);
          GC_push_one ((word) thread_table[i].context.IntT6);
          GC_push_one ((word) thread_table[i].context.IntT7);
          GC_push_one ((word) thread_table[i].context.IntS0);
          GC_push_one ((word) thread_table[i].context.IntS1);
          GC_push_one ((word) thread_table[i].context.IntS2);
          GC_push_one ((word) thread_table[i].context.IntS3);
          GC_push_one ((word) thread_table[i].context.IntS4);
          GC_push_one ((word) thread_table[i].context.IntS5);
          GC_push_one ((word) thread_table[i].context.IntFp);
          GC_push_one ((word) thread_table[i].context.IntA0);
          GC_push_one ((word) thread_table[i].context.IntA1);
          GC_push_one ((word) thread_table[i].context.IntA2);
          GC_push_one ((word) thread_table[i].context.IntA3);
          GC_push_one ((word) thread_table[i].context.IntA4);
          GC_push_one ((word) thread_table[i].context.IntA5);
          GC_push_one ((word) thread_table[i].context.IntT8);
          GC_push_one ((word) thread_table[i].context.IntT9);
          GC_push_one ((word) thread_table[i].context.IntT10);
          GC_push_one ((word) thread_table[i].context.IntT11);
          GC_push_one ((word) thread_table[i].context.IntT12);
          GC_push_one ((word) thread_table[i].context.IntAt);
          GC_push_all_stack((char *) thread_table[i].context.IntSp,
                            thread_table[i].stack);
#       else
              --> architecture not supported
#       endif /* !ALPHA */
#       endif /* !PPC */
#       endif /* !MIPS */
#       endif /* !SHx */
#       endif /* !ARM32 */
#       endif /* !I386 */
      }
    }
}

void GC_get_next_stack(char *start, char **lo, char **hi)
{
    int i;
#   define ADDR_LIMIT (char *)(-1L)
    char * current_min = ADDR_LIMIT;

    for (i = 0; i < MAX_THREADS; i++) {
        char * s = (char *)thread_table[i].stack;

        if (0 != s && s > start && s < current_min) {
            current_min = s;
        }
    }
    *hi = current_min;
    if (current_min == ADDR_LIMIT) {
        *lo = ADDR_LIMIT;
        return;
    }
    *lo = GC_get_lo_stack_addr(current_min);
    if (*lo < start) *lo = start;
}

#if !defined(MSWINCE) && !(defined(__MINGW32__) && !defined(_DLL))

HANDLE WINAPI GC_CreateThread(
    LPSECURITY_ATTRIBUTES lpThreadAttributes, 
    DWORD dwStackSize, LPTHREAD_START_ROUTINE lpStartAddress, 
    LPVOID lpParameter, DWORD dwCreationFlags, LPDWORD lpThreadId )
{
    return CreateThread(lpThreadAttributes, dwStackSize, lpStartAddress,
                        lpParameter, dwCreationFlags, lpThreadId);
}

#else /* !defined(MSWINCE) && !(defined(__MINGW32__) && !defined(_DLL)) */

typedef struct {
    HANDLE child_ready_h, parent_ready_h;
    volatile struct thread_entry * entry;
    LPTHREAD_START_ROUTINE start;
    LPVOID param;
} thread_args;

DWORD WINAPI thread_start(LPVOID arg);

HANDLE WINAPI GC_CreateThread(
    LPSECURITY_ATTRIBUTES lpThreadAttributes, 
    DWORD dwStackSize, LPTHREAD_START_ROUTINE lpStartAddress, 
    LPVOID lpParameter, DWORD dwCreationFlags, LPDWORD lpThreadId )
{
    HANDLE thread_h = NULL;
    HANDLE child_ready_h, parent_ready_h;

    int i;
    thread_args args;

    /* allocate thread slot */
    LOCK();
    for (i = 0; i != MAX_THREADS && thread_table[i].in_use; i++)
        ;
    if (i != MAX_THREADS) {
        thread_table[i].in_use = TRUE;
    }
    UNLOCK();

    if (i != MAX_THREADS) {

        /* create unnamed unsignalled events */
        if (child_ready_h = CreateEvent(NULL, FALSE, FALSE, NULL)) {
            if (parent_ready_h = CreateEvent(NULL, FALSE, FALSE, NULL)) {

                /* set up thread arguments */
                args.child_ready_h = child_ready_h;
                args.parent_ready_h = parent_ready_h;
                args.entry = &thread_table[i];
                args.start = lpStartAddress;
                args.param = lpParameter;

                thread_h = CreateThread(lpThreadAttributes,
                                        dwStackSize, thread_start,
                                        &args,
                                        dwCreationFlags & ~CREATE_SUSPENDED,
                                        lpThreadId);

                if (thread_h) {

                    /* fill in ID and handle; tell child this is done */
                    thread_table[i].id = *lpThreadId;
                    thread_table[i].handle = thread_h;
                    SetEvent (parent_ready_h);

                    /* wait for child to fill in stack and copy args */
                    WaitForSingleObject (child_ready_h, INFINITE);

                    /* suspend the child if requested */
                    if (dwCreationFlags & CREATE_SUSPENDED)
                        SuspendThread (thread_h);

                    /* let child call given function now (or when resumed) */
                    SetEvent (parent_ready_h);

                } else {
                    CloseHandle (parent_ready_h);
                }
            }
        }

        CloseHandle (child_ready_h);

        if (thread_h == NULL)
            thread_table[i].in_use = FALSE;

    } else { /* no thread slot found */
        SetLastError (ERROR_TOO_MANY_TCBS);
    }

    return thread_h;
}

static DWORD WINAPI thread_start(LPVOID arg)
{
    DWORD ret = 0;
    thread_args args = *(thread_args *)arg;

    /* wait for parent to fill in ID and handle */
    WaitForSingleObject (args.parent_ready_h, INFINITE);
    ResetEvent (args.parent_ready_h);

    /* fill in stack; tell parent this is done */
    args.entry->stack = GC_get_stack_base();
    SetEvent (args.child_ready_h);

    /* wait for parent to tell us to go (in case it needs to suspend us) */
    WaitForSingleObject (args.parent_ready_h, INFINITE);
    CloseHandle (args.parent_ready_h);

    /* Clear the thread entry even if we exit with an exception.        */
    /* This is probably pointless, since an uncaught exception is       */
    /* supposed to result in the process being killed.                  */
#ifndef __GNUC__
    __try {
#endif /* __GNUC__ */
        ret = args.start (args.param);
#ifndef __GNUC__
    } __finally {
#endif /* __GNUC__ */
        LOCK();
        args.entry->stack = 0;
        args.entry->in_use = FALSE;
              /* cast away volatile qualifier */
        BZERO((void *) &args.entry->context, sizeof(CONTEXT));
        UNLOCK();
#ifndef __GNUC__
    }
#endif /* __GNUC__ */

    return ret;
}
#endif /* !defined(MSWINCE) && !(defined(__MINGW32__) && !defined(_DLL)) */

#ifdef MSWINCE

typedef struct {
    HINSTANCE hInstance;
    HINSTANCE hPrevInstance;
    LPWSTR lpCmdLine;
    int nShowCmd;
} main_thread_args;

DWORD WINAPI main_thread_start(LPVOID arg);

int WINAPI WinMain(HINSTANCE hInstance, HINSTANCE hPrevInstance,
                   LPWSTR lpCmdLine, int nShowCmd)
{
    DWORD exit_code = 1;

    main_thread_args args = {
        hInstance, hPrevInstance, lpCmdLine, nShowCmd
    };
    HANDLE thread_h;
    DWORD thread_id;

    /* initialize everything */
    InitializeCriticalSection(&GC_allocate_ml);
    GC_init();

    /* start the main thread */
    thread_h = GC_CreateThread(
        NULL, 0, main_thread_start, &args, 0, &thread_id);

    if (thread_h != NULL)
    {
        WaitForSingleObject (thread_h, INFINITE);
        GetExitCodeThread (thread_h, &exit_code);
        CloseHandle (thread_h);
    }

    GC_deinit();
    DeleteCriticalSection(&GC_allocate_ml);

    return (int) exit_code;
}

DWORD WINAPI main_thread_start(LPVOID arg)
{
    main_thread_args * args = (main_thread_args *) arg;

    return (DWORD) GC_WinMain (args->hInstance, args->hPrevInstance,
                               args->lpCmdLine, args->nShowCmd);
}

# else /* !MSWINCE */

LONG WINAPI GC_write_fault_handler(struct _EXCEPTION_POINTERS *exc_info);

/*
 * This isn't generally safe, since DllMain is not premptible.
 * If another thread holds the lock while this runs we're in trouble.
 * Pontus Rydin suggests wrapping the thread start routine instead.
 */
BOOL WINAPI DllMain(HINSTANCE inst, ULONG reason, LPVOID reserved)
{
  switch (reason) {
  case DLL_PROCESS_ATTACH:
    InitializeCriticalSection(&GC_allocate_ml);
    GC_init();  /* Force initialization before thread attach.   */
    /* fall through */
  case DLL_THREAD_ATTACH:
    {
      int i;
      /* It appears to be unsafe to acquire a lock here, since this     */
      /* code is apparently not preeemptible on some systems.           */
      /* (This is based on complaints, not on Microsoft's official      */
      /* documentation, which says this should perform "only simple     */
      /* inititalization tasks".)                                       */
      /* Hence we make do with nonblocking synchronization.             */

      /* The following should be a noop according to the win32  */
      /* documentation.  There is empirical evidence that it    */
      /* isn't.         - HB                                    */
#     ifdef MPROTECT_VDB
       if (GC_incremental) SetUnhandledExceptionFilter(GC_write_fault_handler);
#     endif

      for (i = 0;
                               /* cast away volatile qualifier */
           InterlockedExchange((LPLONG) &thread_table[i].in_use, 1) != 0;
           i++) {
        /* Compare-and-swap would make this cleaner, but that's not     */
        /* supported before Windows 98 and NT 4.0.  In Windows 2000,    */
        /* InterlockedExchange is supposed to be replaced by            */
        /* InterlockedExchangePointer, but that's not really what I     */
        /* want here.                                                   */
        if (i == MAX_THREADS - 1)
          ABORT("too many threads");
      }
      thread_table[i].id = GetCurrentThreadId();
      if (!DuplicateHandle(GetCurrentProcess(),
                           GetCurrentThread(),
                           GetCurrentProcess(),
                           /* cast away volatile qualifier */
                           (HANDLE *) &thread_table[i].handle,
                           0,
                           0,
                           DUPLICATE_SAME_ACCESS)) {
        DWORD last_error = GetLastError();
        GC_printf1("Last error code: %lx\n", last_error);
        ABORT("DuplicateHandle failed");
      }
      thread_table[i].stack = GC_get_stack_base();
      /* If this thread is being created while we are trying to stop    */
      /* the world, wait here.  Hopefully this can't happen on any      */
      /* systems that don't allow us to block here.                     */
      while (GC_please_stop) Sleep(20);
    }
    break;
  case DLL_THREAD_DETACH:
    {
      int i;
      DWORD thread_id = GetCurrentThreadId();
      LOCK();
      for (i = 0;
           i < MAX_THREADS &&
           (thread_table[i].stack == 0 || thread_table[i].id != thread_id);
           i++) {}
      if (i >= MAX_THREADS) {
          WARN("thread %ld not found on detach", (GC_word)thread_id);
      } else {
          thread_table[i].stack = 0;
          thread_table[i].in_use = FALSE;
          CloseHandle(thread_table[i].handle);
            /* cast away volatile qualifier */
          BZERO((void *) &thread_table[i].context, sizeof(CONTEXT));
      }
      UNLOCK();
    }
    break;
  case DLL_PROCESS_DETACH:
    {
      int i;

      LOCK();
      for (i = 0; i < MAX_THREADS; ++i)
      {
          if (thread_table[i].in_use)
          {
              thread_table[i].stack = 0;
              thread_table[i].in_use = FALSE;
              CloseHandle(thread_table[i].handle);
              BZERO((void *) &thread_table[i].context, sizeof(CONTEXT));
          }
      }
      UNLOCK();

      GC_deinit();
      DeleteCriticalSection(&GC_allocate_ml);
    }
    break;

  }
  return TRUE;
}

# endif /* !MSWINCE */

#endif /* GC_WIN32_THREADS */