XlibInt.c

/**************************************************************************/
/*                                                                        */
/* Copyright (c) 2001, 2011 NoMachine (http://www.nomachine.com)          */
/* Copyright (c) 2008-2014 Oleksandr Shneyder <o.shneyder@phoca-gmbh.de>  */
/* Copyright (c) 2011-2016 Mike Gabriel <mike.gabriel@das-netzwerkteam.de>*/
/* Copyright (c) 2014-2016 Mihai Moldovan <ionic@ionic.de>                */
/* Copyright (c) 2014-2016 Ulrich Sibiller <uli42@gmx.de>                 */
/* Copyright (c) 2015-2016 Qindel Group (http://www.qindel.com)           */
/*                                                                        */
/* nx-X11, NX protocol compression and NX extensions to this software     */
/* are copyright of the aforementioned persons and companies.             */
/*                                                                        */
/* Redistribution and use of the present software is allowed according    */
/* to terms specified in the file LICENSE which comes in the source       */
/* distribution.                                                          */
/*                                                                        */
/* All rights reserved.                                                   */
/*                                                                        */
/* NOTE: This software has received contributions from various other      */
/* contributors, only the core maintainers and supporters are listed as   */
/* copyright holders. Please contact us, if you feel you should be listed */
/* as copyright holder, as well.                                          */
/*                                                                        */
/**************************************************************************/

/*

Copyright 1985, 1986, 1987, 1998  The Open Group

Permission to use, copy, modify, distribute, and sell this software and its
documentation for any purpose is hereby granted without fee, provided that
the above copyright notice appear in all copies and that both that
copyright notice and this permission notice appear in supporting
documentation.

The above copyright notice and this permission notice shall be included
in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
IN NO EVENT SHALL THE OPEN GROUP BE LIABLE FOR ANY CLAIM, DAMAGES OR
OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
OTHER DEALINGS IN THE SOFTWARE.

Except as contained in this notice, the name of The Open Group shall
not be used in advertising or otherwise to promote the sale, use or
other dealings in this Software without prior written authorization
from The Open Group.

*/

/*
 *	XlibInt.c - Internal support routines for the C subroutine
 *	interface library (Xlib) to the X Window System Protocol V11.0.
 */

#ifdef WIN32
#define _XLIBINT_
#endif
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include "Xlibint.h"
#include "Xprivate.h"
#include <nx-X11/Xpoll.h>
#if !USE_XCB
#include <nx-X11/Xtrans/Xtrans.h>
#include <nx-X11/extensions/xcmiscstr.h>
#endif /* !USE_XCB */
#include <assert.h>
#include <stdio.h>
#ifdef WIN32
#include <direct.h>
#endif

#ifdef XTHREADS
#include "locking.h"

/* these pointers get initialized by XInitThreads */
LockInfoPtr _Xglobal_lock = NULL;
void (*_XCreateMutex_fn)(LockInfoPtr) = NULL;
/* struct _XCVList *(*_XCreateCVL_fn)() = NULL; */
void (*_XFreeMutex_fn)(LockInfoPtr) = NULL;
void (*_XLockMutex_fn)(
    LockInfoPtr /* lock */
#if defined(XTHREADS_WARN) || defined(XTHREADS_FILE_LINE)
    , char * /* file */
    , int /* line */
#endif
    ) = NULL;
void (*_XUnlockMutex_fn)(
    LockInfoPtr /* lock */
#if defined(XTHREADS_WARN) || defined(XTHREADS_FILE_LINE)
    , char * /* file */
    , int /* line */
#endif
    ) = NULL;
xthread_t (*_Xthread_self_fn)(void) = NULL;

#define XThread_Self()	((*_Xthread_self_fn)())

#if !USE_XCB
#define UnlockNextReplyReader(d) if ((d)->lock) \
    (*(d)->lock->pop_reader)((d),&(d)->lock->reply_awaiters,&(d)->lock->reply_awaiters_tail)

#define QueueReplyReaderLock(d) ((d)->lock ? \
    (*(d)->lock->push_reader)(d,&(d)->lock->reply_awaiters_tail) : NULL)
#define QueueEventReaderLock(d) ((d)->lock ? \
    (*(d)->lock->push_reader)(d,&(d)->lock->event_awaiters_tail) : NULL)
#endif /* !USE_XCB */

#else /* XTHREADS else */

#if !USE_XCB
#define UnlockNextReplyReader(d)
#define UnlockNextEventReader(d)
#endif /* !USE_XCB */

#endif /* XTHREADS else */

#ifdef NX_TRANS_SOCKET

#include <nx/NX.h>
#include <nx/NXvars.h>

static struct timeval retry;

/*
 * From Xtranssock.c. Presently the congestion state
 * is reported by the proxy to the application, by
 * invoking the callback directly. The function will
 * be possibly used in the future, to be able to track
 * the bandwidth usage even when the NX transport is
 * not running. Note that in this sample implementation
 * the congestion state is checked very often and can
 * be surely optimized.
 */

#ifdef NX_TRANS_CHANGE
extern int _X11TransSocketCongestionChange(XtransConnInfo, int *);
#endif

#endif /* #ifdef NX_TRANS_SOCKET */

/* check for both EAGAIN and EWOULDBLOCK, because some supposedly POSIX
 * systems are broken and return EWOULDBLOCK when they should return EAGAIN
 */
#ifdef WIN32
#define ETEST() (WSAGetLastError() == WSAEWOULDBLOCK)
#else
#ifdef __CYGWIN__ /* Cygwin uses ENOBUFS to signal socket is full */
#define ETEST() (errno == EAGAIN || errno == EWOULDBLOCK || errno == ENOBUFS)
#else
#if defined(EAGAIN) && defined(EWOULDBLOCK)
#define ETEST() (errno == EAGAIN || errno == EWOULDBLOCK)
#else
#ifdef EAGAIN
#define ETEST() (errno == EAGAIN)
#else
#define ETEST() (errno == EWOULDBLOCK)
#endif /* EAGAIN */
#endif /* EAGAIN && EWOULDBLOCK */
#endif /* __CYGWIN__ */
#endif /* WIN32 */

#ifdef WIN32
#define ECHECK(err) (WSAGetLastError() == err)
#define ESET(val) WSASetLastError(val)
#else
#define ECHECK(err) (errno == err)
#define ESET(val) errno = val
#endif

#if defined(LOCALCONN) || defined(LACHMAN)
#ifdef EMSGSIZE
#define ESZTEST() (ECHECK(EMSGSIZE) || ECHECK(ERANGE))
#else
#define ESZTEST() ECHECK(ERANGE)
#endif
#else
#ifdef EMSGSIZE
#define ESZTEST() ECHECK(EMSGSIZE)
#endif
#endif

#if !USE_XCB

#define STARTITERATE(tpvar,type,start,endcond) \
  for (tpvar = (type *) (start); endcond; )
#define ITERPTR(tpvar) (char *)tpvar
#define RESETITERPTR(tpvar,type,start) tpvar = (type *) (start)
#define INCITERPTR(tpvar,type) tpvar++
#define ENDITERATE


typedef union {
    xReply rep;
    char buf[BUFSIZE];
} _XAlignedBuffer;

static char *_XAsyncReply(
    Display *dpy,
    register xReply *rep,
    char *buf,
    register int *lenp,
    Bool discard);
#endif /* !USE_XCB */

/*
 * The following routines are internal routines used by Xlib for protocol
 * packet transmission and reception.
 *
 * _XIOError(Display *) will be called if any sort of system call error occurs.
 * This is assumed to be a fatal condition, i.e., XIOError should not return.
 *
 * _XError(Display *, xError *) will be called whenever an X_Error event is
 * received.  This is not assumed to be a fatal condition, i.e., it is
 * acceptable for this procedure to return.  However, XError should NOT
 * perform any operations (directly or indirectly) on the DISPLAY.
 *
 * Routines declared with a return type of 'Status' return 0 on failure,
 * and non 0 on success.  Routines with no declared return type don't
 * return anything.  Whenever possible routines that create objects return
 * the object they have created.
 */

#if !USE_XCB
static xReq _dummy_request = {
	0, 0, 0
};

#ifdef NX_TRANS_SOCKET

/*
 * Replace the standard Select with a version giving NX a
 * chance to check its own descriptors. This doesn't cover
 * the cases where the system is using poll or when system-
 * specific defines override the Select definition (OS/2).
 */

int _XSelect(int maxfds, fd_set *readfds, fd_set *writefds,
                 fd_set *exceptfds, struct timeval *timeout)
{
#ifdef NX_TRANS_TEST
    fprintf(stderr, "_XSelect: Called with [%d][%p][%p][%p][%p].\n",
                maxfds, (void *) readfds, (void *) writefds, (void *) exceptfds,
                    (void *) timeout);
#endif

    if (NXTransRunning(NX_FD_ANY))
    {
        fd_set t_readfds, t_writefds;
        struct timeval t_timeout;

        int n, r, e;

#ifdef NX_TRANS_TEST

        if (exceptfds != NULL)
        {
            fprintf(stderr, "_XSelect: WARNING! Can't handle exception fds in select.\n");
        }

#endif

        if (readfds == NULL)
        {
            FD_ZERO(&t_readfds);

            readfds = &t_readfds;
        }

        if (writefds == NULL)
        {
            FD_ZERO(&t_writefds);

            writefds = &t_writefds;
        }

        if (timeout == NULL)
        {
            t_timeout.tv_sec  = 10;
            t_timeout.tv_usec = 0;

            timeout = &t_timeout;
        }

        n = maxfds;

        /*
         * If the transport is gone avoid
         * sleeping until the timeout.
         */

        if (NXTransPrepare(&n, readfds, writefds, timeout) != 0)
        {
          NXTransSelect(&r, &e, &n, readfds, writefds, timeout);

          NXTransExecute(&r, &e, &n, readfds, writefds, timeout);

          errno = e;

          return r;
        }
        else
        {
          return 0;
        }
    }
    else
    {
        return select(maxfds, readfds, writefds, exceptfds, timeout);
    }
}

#else /* #ifdef NX_TRANS_SOCKET */

int _XSelect(int maxfds, fd_set *readfds, fd_set *writefds,
                 fd_set *exceptfds, struct timeval *timeout)
{
    return select(maxfds, readfds, writefds, exceptfds, timeout);
}

#endif /* #ifdef NX_TRANS_SOCKET */

/*
 * This is an OS dependent routine which:
 * 1) returns as soon as the connection can be written on....
 * 2) if the connection can be read, must enqueue events and handle errors,
 * until the connection is writable.
 */
static void
_XWaitForWritable(
    Display *dpy
#ifdef XTHREADS
    ,
    xcondition_t cv		/* our reading condition variable */
#endif
    )
{
#ifdef USE_POLL
    struct pollfd filedes;
#else
    fd_set r_mask;
    fd_set w_mask;
#endif
    int nfound;

#ifdef NX_TRANS_SOCKET
#if defined(NX_TRANS_CHANGE)
    int congestion;
#endif
    if (_XGetIOError(dpy)) {
        return;
    }
#endif

#ifdef USE_POLL
    filedes.fd = dpy->fd;
    filedes.events = 0;
#else
    FD_ZERO(&r_mask);
    FD_ZERO(&w_mask);
#endif

    for (;;) {
#ifdef XTHREADS
	/* We allow only one thread at a time to read, to minimize
	   passing of read data between threads.
	   Now, who is it?  If there is a non-NULL reply_awaiters and
	   we (i.e., our cv) are not at the head of it, then whoever
	   is at the head is the reader, and we don't read.
	   Otherwise there is no reply_awaiters or we are at the
	   head, having just appended ourselves.
	   In this case, if there is a event_awaiters, then whoever
	   is at the head of it got there before we did, and they are the
	   reader.

	   Last cases: no event_awaiters and we are at the head of
	   reply_awaiters or reply_awaiters is NULL: we are the reader,
	   since there is obviously no one else involved.

	   XXX - what if cv is NULL and someone else comes along after
	   us while we are waiting?
	   */

	if (!dpy->lock ||
	    (!dpy->lock->event_awaiters &&
	     (!dpy->lock->reply_awaiters ||
	      dpy->lock->reply_awaiters->cv == cv)))
#endif

#ifndef NX_TRANS_SOCKET
#ifdef USE_POLL
	    filedes.events = POLLIN;
	filedes.events |= POLLOUT;
#else
	FD_SET(dpy->fd, &r_mask);
        FD_SET(dpy->fd, &w_mask);
#endif
#endif /* #ifndef NX_TRANS_SOCKET */

	do {
#ifdef NX_TRANS_SOCKET
            /*
             * Give a chance to the registered client to perform
             * any needed operation before entering the select.
             */

#ifdef NX_TRANS_TEST
            fprintf(stderr, "_XWaitForWritable: WAIT! Waiting for the display to become writable.\n");
#endif
            NXTransFlush(dpy->fd);

            if (_NXDisplayBlockFunction != NULL) {
                    (*_NXDisplayBlockFunction)(dpy, NXBlockWrite);
            }

            /*
             * Need to set again the descriptors as we could have
             * run multiple selects before having the possibility
             * to read or write to the X connection.
             */

#ifdef USE_POLL
            filedes.events = POLLIN;
            filedes.events |= POLLOUT;
#else
            FD_SET(dpy->fd, &r_mask);
            FD_SET(dpy->fd, &w_mask);
#endif
#endif /* #ifdef NX_TRANS_SOCKET */
	    UnlockDisplay(dpy);
#ifdef USE_POLL
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
            fprintf(stderr, "_XWaitForWritable: Calling poll().\n");
#endif
	    nfound = poll (&filedes, 1, -1);
#else /* USE_POLL */
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
            fprintf(stderr, "_XWaitForWritable: Calling select() after [%ld] ms.\n",
                        NXTransTime());
#endif /* defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG) */
#ifdef NX_TRANS_SOCKET
            /*
             * Give a chance to the callback to detect
             * the failure of the display even if we
             * miss the interrupt inside the select.
             */

            if (_NXDisplayErrorFunction != NULL) {
                retry.tv_sec  = 5;
                retry.tv_usec = 0;
                nfound = Select (dpy->fd + 1, &r_mask, &w_mask, NULL, &retry);
            } else {
                nfound = Select (dpy->fd + 1, &r_mask, &w_mask, NULL, NULL);
            }
#else /* NX_TRANS_SOCKET */
	    nfound = Select (dpy->fd + 1, &r_mask, &w_mask, NULL, NULL);
#endif /* NX_TRANS_SOCKET */
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
            fprintf(stderr, "_XWaitForWritable: Out of select() with [%d] after [%ld] ms.\n",
                        nfound, NXTransTime());

            if (FD_ISSET(dpy->fd, &r_mask))
            {
                BytesReadable_t pend;

                _X11TransBytesReadable(dpy->trans_conn, &pend);

                fprintf(stderr, "_XWaitForWritable: Descriptor [%d] is ready with [%ld] bytes to read.\n",
                            dpy->fd, pend);
            }

            if (FD_ISSET(dpy->fd, &w_mask))
            {
              fprintf(stderr, "_XWaitForWritable: Descriptor [%d] has become writable.\n\n",
                          dpy->fd);
            }
#endif /* defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG) */
#endif /* USE_POLL */
	    InternalLockDisplay(dpy, cv != NULL);
#ifdef NX_TRANS_SOCKET
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
            if (_NXDisplayCongestionFunction != NULL &&
                    _X11TransSocketCongestionChange(dpy->trans_conn, &congestion) == 1) {
                (*_NXDisplayCongestionFunction)(dpy, congestion);
            }
#endif /* defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE) */
            if (nfound <= 0) {
	      if ((nfound == -1 && !(ECHECK(EINTR) || ETEST())) ||
                        (_NXDisplayErrorFunction != NULL &&
                            (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                    _XIOError(dpy);
                    return;
                }
              }
#else /* NX_TRANS_SOCKET */
	    if (nfound < 0 && !(ECHECK(EINTR) || ETEST()))
		_XIOError(dpy);
#endif /* NX_TRANS_SOCKET */
	} while (nfound <= 0);

	if (
#ifdef USE_POLL
	    filedes.revents & POLLIN
#else /* USE_POLL */
	    FD_ISSET(dpy->fd, &r_mask)
#endif /* USE_POLL */
	    )
	{
	    _XAlignedBuffer buf;
	    BytesReadable_t pend;
	    register int len;
	    register xReply *rep;

	    /* find out how much data can be read */
	    if (_X11TransBytesReadable(dpy->trans_conn, &pend) < 0)
#ifdef NX_TRANS_SOCKET
            {
                _XIOError(dpy);

                return;
            }
#else /* NX_TRANS_SOCKET */
		_XIOError(dpy);
#endif /* NX_TRANS_SOCKET */
	    len = pend;

	    /* must read at least one xEvent; if none is pending, then
	       we'll just block waiting for it */
	    if (len < SIZEOF(xReply)
#ifdef XTHREADS
		|| dpy->async_handlers
#endif
		)
		len = SIZEOF(xReply);

	    /* but we won't read more than the max buffer size */
	    if (len > BUFSIZE) len = BUFSIZE;

	    /* round down to an integral number of XReps */
	    len = (len / SIZEOF(xReply)) * SIZEOF(xReply);

	    (void) _XRead (dpy, buf.buf, (long) len);

	    STARTITERATE(rep,xReply,buf.buf,len > 0) {
		if (rep->generic.type == X_Reply) {
                    int tmp = len;
		    RESETITERPTR(rep,xReply,
				 _XAsyncReply (dpy, rep,
					       ITERPTR(rep), &tmp, True));
                    len = tmp;
		    pend = len;
		} else {
		    if (rep->generic.type == X_Error)
			_XError (dpy, (xError *)rep);
		    else	/* must be an event packet */
			_XEnq (dpy, (xEvent *)rep);
		    INCITERPTR(rep,xReply);
		    len -= SIZEOF(xReply);
		}
	    } ENDITERATE
#ifdef XTHREADS
	    if (dpy->lock && dpy->lock->event_awaiters)
		ConditionSignal(dpy, dpy->lock->event_awaiters->cv);
#endif
	}
#ifdef USE_POLL
	if (filedes.revents & (POLLOUT|POLLHUP|POLLERR))
#else
	if (FD_ISSET(dpy->fd, &w_mask))
#endif
	{
#ifdef XTHREADS
	    if (dpy->lock) {
		ConditionBroadcast(dpy, dpy->lock->writers);
	    }
#endif
	    return;
	}
    }
}
#endif /* !USE_XCB */


#define POLLFD_CACHE_SIZE 5

/* initialize the struct array passed to poll() below */
Bool _XPollfdCacheInit(
    Display *dpy)
{
#ifdef USE_POLL
    struct pollfd *pfp;

    pfp = Xmalloc(POLLFD_CACHE_SIZE * sizeof(struct pollfd));
    if (!pfp)
	return False;
    pfp[0].fd = dpy->fd;
    pfp[0].events = POLLIN;

    dpy->filedes = (XPointer)pfp;
#endif
    return True;
}

void _XPollfdCacheAdd(
    Display *dpy,
    int fd)
{
#ifdef USE_POLL
    struct pollfd *pfp = (struct pollfd *)dpy->filedes;

    if (dpy->im_fd_length <= POLLFD_CACHE_SIZE) {
	pfp[dpy->im_fd_length].fd = fd;
	pfp[dpy->im_fd_length].events = POLLIN;
    }
#endif
}

/* ARGSUSED */
void _XPollfdCacheDel(
    Display *dpy,
    int fd)			/* not used */
{
#ifdef USE_POLL
    struct pollfd *pfp = (struct pollfd *)dpy->filedes;
    struct _XConnectionInfo *conni;

    /* just recalculate whole list */
    if (dpy->im_fd_length <= POLLFD_CACHE_SIZE) {
	int loc = 1;
	for (conni = dpy->im_fd_info; conni; conni=conni->next) {
	    pfp[loc].fd = conni->fd;
	    pfp[loc].events = POLLIN;
	    loc++;
	}
    }
#endif
}

#if !USE_XCB
/* returns True iff there is an event in the queue newer than serial_num */

static Bool
_XNewerQueuedEvent(
    Display *dpy,
    int serial_num)
{
    _XQEvent *qev;

    if (dpy->next_event_serial_num == serial_num)
	return False;

    qev = dpy->head;
    while (qev) {
	if (qev->qserial_num >= serial_num) {
	    return True;
	}
	qev = qev->next;
    }
    return False;
}

static int
_XWaitForReadable(
  Display *dpy)
{
    int result;
    int fd = dpy->fd;
    struct _XConnectionInfo *ilist;
    register int saved_event_serial = 0;
    int in_read_events = 0;
    register Bool did_proc_conni = False;
#ifdef USE_POLL
    struct pollfd *filedes;
#else
    fd_set r_mask;
    int highest_fd = fd;
#endif

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
    int congestion;
#endif
#ifdef NX_TRANS_SOCKET
    if (_XGetIOError(dpy)) {
        return -1;
    }
#endif

#ifdef USE_POLL
    if (dpy->im_fd_length + 1 > POLLFD_CACHE_SIZE
	&& !(dpy->flags & XlibDisplayProcConni)) {
	/* XXX - this fallback is gross */
	int i;

	filedes = (struct pollfd *)Xmalloc(dpy->im_fd_length * sizeof(struct pollfd));
	filedes[0].fd = fd;
	filedes[0].events = POLLIN;
	for (ilist=dpy->im_fd_info, i=1; ilist; ilist=ilist->next, i++) {
	    filedes[i].fd = ilist->fd;
	    filedes[i].events = POLLIN;
	}
    } else {
	filedes = (struct pollfd *)dpy->filedes;
    }
#else /* USE_POLL */
    FD_ZERO(&r_mask);
#endif /* USE_POLL */
    for (;;) {
#ifndef USE_POLL
	FD_SET(fd, &r_mask);
	if (!(dpy->flags & XlibDisplayProcConni))
	    for (ilist=dpy->im_fd_info; ilist; ilist=ilist->next) {
		FD_SET(ilist->fd, &r_mask);
		if (ilist->fd > highest_fd)
		    highest_fd = ilist->fd;
	    }
#endif /* USE_POLL */
	UnlockDisplay(dpy);
#ifdef USE_POLL
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        fprintf(stderr, "_XWaitForReadable: Calling poll().\n");
#endif
	result = poll(filedes,
		      (dpy->flags & XlibDisplayProcConni) ? 1 : 1+dpy->im_fd_length,
		      -1);
#else /* USE_POLL */
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        fprintf(stderr, "_XWaitForReadable: Calling select().\n");
#endif
#ifdef NX_TRANS_SOCKET
        /*
         * Give a chance to the registered application
         * to perform any needed operation.
         */

#ifdef NX_TRANS_TEST
        fprintf(stderr, "_XWaitForReadable: WAIT! Waiting for the display to become readable.\n");
#endif
        NXTransFlush(dpy->fd);

        if (_NXDisplayBlockFunction != NULL) {
            (*_NXDisplayBlockFunction)(dpy, NXBlockRead);
        }

        if (_NXDisplayErrorFunction != NULL) {
            retry.tv_sec  = 5;
            retry.tv_usec = 0;
            result = Select(highest_fd + 1, &r_mask, NULL, NULL, &retry);
        } else {
            result = Select(highest_fd + 1, &r_mask, NULL, NULL, NULL);
        }
#else /*  NX_TRANS_SOCKET */
	result = Select(highest_fd + 1, &r_mask, NULL, NULL, NULL);
#endif /* NX_TRANS_SOCKET */
#endif /* USE_POLL */
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        fprintf(stderr, "_XWaitForReadable: Out of select with result [%d] and errno [%d].\n",
                    result, (result < 0 ? errno : 0));
#endif
	InternalLockDisplay(dpy, dpy->flags & XlibDisplayReply);
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        if (_NXDisplayCongestionFunction != NULL &&
                _X11TransSocketCongestionChange(dpy->trans_conn, &congestion) == 1) {
            (*_NXDisplayCongestionFunction)(dpy, congestion);
        }
#endif
#ifdef NX_TRANS_SOCKET
        if (result <= 0) {
	  if ((result == -1 && !(ECHECK(EINTR) || ETEST())) ||
                    (_NXDisplayErrorFunction != NULL &&
                        (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                _XIOError(dpy);
                return -1;
            }
            continue;
        }
#else
	if (result == -1 && !(ECHECK(EINTR) || ETEST())) _XIOError(dpy);
	if (result <= 0)
	    continue;
#endif
#ifdef USE_POLL
	if (filedes[0].revents & (POLLIN|POLLHUP|POLLERR))
#else
	if (FD_ISSET(fd, &r_mask))
#endif
	    break;
	if (!(dpy->flags & XlibDisplayProcConni)) {
	    int i;

	    saved_event_serial = dpy->next_event_serial_num;
	    /* dpy flags can be clobbered by internal connection callback */
	    in_read_events = dpy->flags & XlibDisplayReadEvents;
	    for (ilist=dpy->im_fd_info, i=1; ilist; ilist=ilist->next, i++) {
#ifdef USE_POLL
		if (filedes[i].revents & POLLIN)
#else
		if (FD_ISSET(ilist->fd, &r_mask))
#endif
		{
		    _XProcessInternalConnection(dpy, ilist);
		    did_proc_conni = True;
		}
	    }
#ifdef USE_POLL
	    if (dpy->im_fd_length + 1 > POLLFD_CACHE_SIZE)
		Xfree(filedes);
#endif
	}
	if (did_proc_conni) {
	    /* some internal connection callback might have done an
	       XPutBackEvent.  We notice it here and if we needed an event,
	       we can return all the way. */
	    if (_XNewerQueuedEvent(dpy, saved_event_serial)
		&& (in_read_events
#ifdef XTHREADS
		    || (dpy->lock && dpy->lock->event_awaiters)
#endif
		    ))
		return -2;
	    did_proc_conni = False;
	}
    }
#ifdef XTHREADS
#ifdef XTHREADS_DEBUG
    printf("thread %x _XWaitForReadable returning\n", XThread_Self());
#endif
#endif
    return 0;
}
#endif /* !USE_XCB */

static int sync_hazard(Display *dpy)
{
    /*
     * "span" and "hazard" need to be signed such that the ">=" comparision
     * works correctly in the case that hazard is greater than 65525
     */
    int64_t span = X_DPY_GET_REQUEST(dpy) - X_DPY_GET_LAST_REQUEST_READ(dpy);
    int64_t hazard = min((dpy->bufmax - dpy->buffer) / SIZEOF(xReq), 65535 - 10);
    return span >= 65535 - hazard - 10;
}

static
void sync_while_locked(Display *dpy)
{
#ifdef XTHREADS
    if (dpy->lock)
        (*dpy->lock->user_lock_display)(dpy);
#endif
    UnlockDisplay(dpy);
    SyncHandle();
    InternalLockDisplay(dpy, /* don't skip user locks */ 0);
#ifdef XTHREADS
    if (dpy->lock)
        (*dpy->lock->user_unlock_display)(dpy);
#endif
}

void _XSeqSyncFunction(
    register Display *dpy)
{
    xGetInputFocusReply rep;
    _X_UNUSED register xReq *req;

#ifdef NX_TRANS_SOCKET
#ifdef NX_TRANS_DEBUG
    fprintf(stderr, "_XSeqSyncFunction: Going to synchronize the display.\n");
#endif

    if (dpy->flags & XlibDisplayIOError)
    {
#ifdef NX_TRANS_DEBUG
        fprintf(stderr, "_XSeqSyncFunction: Returning with I/O error detected.\n");
#endif
        return;
    }
#endif /* NX_TRANS_SOCKET */
    if ((X_DPY_GET_REQUEST(dpy) - X_DPY_GET_LAST_REQUEST_READ(dpy)) >= (65535 - BUFSIZE/SIZEOF(xReq))) {
	GetEmptyReq(GetInputFocus, req);
	(void) _XReply (dpy, (xReply *)&rep, 0, xTrue);
	sync_while_locked(dpy);
    } else if (sync_hazard(dpy))
	_XSetPrivSyncFunction(dpy);
}

/* NOTE: only called if !XTHREADS, or when XInitThreads wasn't called. */
static int
_XPrivSyncFunction (Display *dpy)
{
#ifdef NX_TRANS_SOCKET
    if (dpy->flags & XlibDisplayIOError)
    {
#ifdef NX_TRANS_DEBUG
        fprintf(stderr, "%s: Returning 0 with I/O error detected.\n", __func__);
#endif
        return 0;
    }
#endif /* NX_TRANS_SOCKET */

#ifdef XTHREADS
    assert(!dpy->lock_fns);
#endif
    assert(dpy->synchandler == _XPrivSyncFunction);
    assert((dpy->flags & XlibDisplayPrivSync) != 0);
    dpy->synchandler = dpy->savedsynchandler;
    dpy->savedsynchandler = NULL;
    dpy->flags &= ~XlibDisplayPrivSync;
    if(dpy->synchandler)
        dpy->synchandler(dpy);
    _XIDHandler(dpy);
    _XSeqSyncFunction(dpy);
    return 0;
}

void _XSetPrivSyncFunction(Display *dpy)
{
#ifdef XTHREADS
    if (dpy->lock_fns)
        return;
#endif
    if (!(dpy->flags & XlibDisplayPrivSync)) {
	dpy->savedsynchandler = dpy->synchandler;
	dpy->synchandler = _XPrivSyncFunction;
	dpy->flags |= XlibDisplayPrivSync;
    }
}

void _XSetSeqSyncFunction(Display *dpy)
{
    if (sync_hazard(dpy))
	_XSetPrivSyncFunction (dpy);
}

#if !USE_XCB
#ifdef XTHREADS
static void _XFlushInt(
        register Display *dpy,
        register xcondition_t cv);
#endif

/*
 * _XFlush - Flush the X request buffer.  If the buffer is empty, no
 * action is taken.  This routine correctly handles incremental writes.
 * This routine may have to be reworked if int < long.
 */
void _XFlush(
	register Display *dpy)
{
#ifdef XTHREADS
    /* With multi-threading we introduce an internal routine to which
       we can pass a condition variable to do locking correctly. */

    _XFlushInt(dpy, NULL);
}

/* _XFlushInt - Internal version of _XFlush used to do multi-threaded
 * locking correctly.
 */

static void _XFlushInt(
	register Display *dpy,
        register xcondition_t cv)
{
#endif /* XTHREADS*/
	register long size, todo;
	register int write_stat;
	register char *bufindex;
	_XExtension *ext;
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        int congestion;
#endif

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        fprintf(stderr, "_XFlushInt: Entering flush with [%d] bytes to write.\n",
                    (dpy->bufptr - dpy->buffer));
#endif
	/* This fix resets the bufptr to the front of the buffer so
	 * additional appends to the bufptr will not corrupt memory. Since
	 * the server is down, these appends are no-op's anyway but
	 * callers of _XFlush() are not verifying this before they call it.
	 */
	if (dpy->flags & XlibDisplayIOError)
	{
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        fprintf(stderr, "_XFlushInt: Returning with I/O error detected.\n");
#endif
	    dpy->bufptr = dpy->buffer;
	    dpy->last_req = (char *)&_dummy_request;
	    return;
	}

#ifdef XTHREADS
#ifdef NX_TRANS_SOCKET
        while (dpy->flags & XlibDisplayWriting) {
            if (_XGetIOError(dpy)) {
                return;
            }
#else
	while (dpy->flags & XlibDisplayWriting) {
#endif
	    if (dpy->lock) {
		ConditionWait(dpy, dpy->lock->writers);
	    } else {
		_XWaitForWritable (dpy, cv);
	    }
	}
#endif
	size = todo = dpy->bufptr - dpy->buffer;
	if (!size) return;
#ifdef XTHREADS
	dpy->flags |= XlibDisplayWriting;
	/* make sure no one else can put in data */
	dpy->bufptr = dpy->bufmax;
#endif
	for (ext = dpy->flushes; ext; ext = ext->next_flush)
	    (*ext->before_flush)(dpy, &ext->codes, dpy->buffer, size);
	bufindex = dpy->buffer;
	/*
	 * While write has not written the entire buffer, keep looping
	 * until the entire buffer is written.  bufindex will be
	 * incremented and size decremented as buffer is written out.
	 */
	while (size) {
	    ESET(0);
	    write_stat = _X11TransWrite(dpy->trans_conn,
					bufindex, (int) todo);
	    if (write_stat >= 0) {
#ifdef NX_TRANS_SOCKET
                if (_NXDisplayWriteFunction != NULL) {
                    (*_NXDisplayWriteFunction)(dpy, write_stat);
                }
#ifdef NX_TRANS_CHANGE
                if (_NXDisplayCongestionFunction != NULL &&
                        _X11TransSocketCongestionChange(dpy->trans_conn, &congestion) == 1) {
                    (*_NXDisplayCongestionFunction)(dpy, congestion);
                }
#endif
#endif
		size -= write_stat;
		todo = size;
		bufindex += write_stat;
	    } else if (ETEST()) {
		_XWaitForWritable(dpy
#ifdef XTHREADS
				  , cv
#endif
				  );
#ifdef SUNSYSV
	    } else if (ECHECK(0)) {
		_XWaitForWritable(dpy
#ifdef XTHREADS
				  , cv
#endif
				  );
#endif
#ifdef ESZTEST
	    } else if (ESZTEST()) {
		if (todo > 1)
		    todo >>= 1;
		else {
		    _XWaitForWritable(dpy
#ifdef XTHREADS
				      , cv
#endif
				      );
		}
#endif
#ifdef NX_TRANS_SOCKET
            } else if (!ECHECK(EINTR) ||
                (_NXDisplayErrorFunction != NULL &&
                    (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                _XIOError(dpy);
                return;
            }
#else
	    } else if (!ECHECK(EINTR)) {
		/* Write failed! */
		/* errno set by write system call. */
		_XIOError(dpy);
	    }
#endif
#ifdef NX_TRANS_SOCKET
            if (_XGetIOError(dpy)) {
                return;
            }
#endif
	}
	dpy->last_req = (char *)&_dummy_request;
	_XSetSeqSyncFunction(dpy);
	dpy->bufptr = dpy->buffer;
#ifdef XTHREADS
	dpy->flags &= ~XlibDisplayWriting;
#endif
}

int
_XEventsQueued(
    register Display *dpy,
    int mode)
{
	register int len;
	BytesReadable_t pend;
	_XAlignedBuffer buf;
	register xReply *rep;
	char *read_buf;
#ifdef XTHREADS
	int entry_event_serial_num;
	struct _XCVList *cvl = NULL;
	xthread_t self;

#ifdef XTHREADS_DEBUG
	printf("_XEventsQueued called in thread %x\n", XThread_Self());
#endif
#endif /* XTHREADS*/

	if (mode == QueuedAfterFlush)
	{
	    _XFlush(dpy);
	    if (dpy->qlen)
		return(dpy->qlen);
	}
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        if (dpy->flags & XlibDisplayIOError) {
            fprintf(stderr, "_XEventsQueued: Returning [%d] after display failure.\n",
                        dpy->qlen);
        }
#endif
	if (dpy->flags & XlibDisplayIOError) return(dpy->qlen);

#ifdef XTHREADS
	/* create our condition variable and append to list,
	 * unless we were called from within XProcessInternalConnection
	 * or XLockDisplay
	 */
	xthread_clear_id(self);
	if (dpy->lock && (xthread_have_id (dpy->lock->conni_thread)
			  || xthread_have_id (dpy->lock->locking_thread)))
	    /* some thread is in XProcessInternalConnection or XLockDisplay
	       so we have to see if we are it */
	    self = XThread_Self();
	if (!xthread_have_id(self)
	    || (!xthread_equal(self, dpy->lock->conni_thread)
		&& !xthread_equal(self, dpy->lock->locking_thread))) {
	    /* In the multi-threaded case, if there is someone else
	       reading events, then there aren't any available, so
	       we just return.  If we waited we would block.
	       */
	    if (dpy->lock && dpy->lock->event_awaiters)
		return dpy->qlen;
	    /* nobody here but us, so lock out any newcomers */
	    cvl = QueueEventReaderLock(dpy);
	}

	while (dpy->lock && cvl && dpy->lock->reply_first) {
	    /* note which events we have already seen so we'll know
	       if _XReply (in another thread) reads one */
	    entry_event_serial_num = dpy->next_event_serial_num;
	    ConditionWait(dpy, cvl->cv);
	    /* did _XReply read an event we can return? */
	    if (_XNewerQueuedEvent(dpy, entry_event_serial_num))
	    {
		UnlockNextEventReader(dpy);
		return 0;
	    }
	}
#endif /* XTHREADS*/

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
        fprintf(stderr, "_XEventsQueued: Checking bytes readable.\n");
#endif
	if (_X11TransBytesReadable(dpy->trans_conn, &pend) < 0)
#ifdef NX_TRANS_SOCKET
        {
            _XIOError(dpy);

            return (dpy->qlen);
        }
#else
	    _XIOError(dpy);
#endif
#ifdef XCONN_CHECK_FREQ
	/* This is a crock, required because FIONREAD or equivalent is
	 * not guaranteed to detect a broken connection.
	 */
	if (!pend && !dpy->qlen && ++dpy->conn_checker >= XCONN_CHECK_FREQ)
	{
	    int	result;
#ifdef USE_POLL
	    struct pollfd filedes;
#else
	    fd_set r_mask;
	    static struct timeval zero_time;
#endif

	    dpy->conn_checker = 0;
#ifdef USE_POLL
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
            fprintf(stderr, "_XEventsQueued: Calling poll().\n");
#endif
	    filedes.fd = dpy->fd;
	    filedes.events = POLLIN;
	    if ((result = poll(&filedes, 1, 0)))
#else
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
            fprintf(stderr, "_XEventsQueued: Calling select().\n");
#endif
	    FD_ZERO(&r_mask);
	    FD_SET(dpy->fd, &r_mask);
	    if ((result = Select(dpy->fd + 1, &r_mask, NULL, NULL, &zero_time)))
#endif
	    {
		if (result > 0)
		{
		    if (_X11TransBytesReadable(dpy->trans_conn, &pend) < 0)
#ifdef NX_TRANS_SOCKET
                    {
                        _XIOError(dpy);

                        return (dpy->qlen);
                    }
#else
			_XIOError(dpy);
#endif
		    /* we should not get zero, if we do, force a read */
		    if (!pend)
			pend = SIZEOF(xReply);
		}
#ifdef NX_TRANS_SOCKET
                if (result <= 0) {
		  if ((result == -1 && !(ECHECK(EINTR) || ETEST())) ||
                            (_NXDisplayErrorFunction != NULL &&
                                (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                        _XIOError(dpy);
                        return (dpy->qlen);
                    }
                }
#else
		else if (result < 0 && !(ECHECK(EINTR) || ETEST()))
#endif
		    _XIOError(dpy);
	    }
	}
#endif /* XCONN_CHECK_FREQ */
	if (!(len = pend)) {
	    /* _XFlush can enqueue events */
#ifdef XTHREADS
	    if (cvl)
#endif
	    {
		UnlockNextEventReader(dpy);
	    }
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
            fprintf(stderr, "_XEventsQueued: Returning [%d].\n", dpy->qlen);
#endif
	    return(dpy->qlen);
	}
      /* Force a read if there is not enough data.  Otherwise,
       * a select() loop at a higher-level will spin undesirably,
       * and we've seen at least one OS that appears to not update
       * the result from FIONREAD once it has returned nonzero.
       */
#ifdef XTHREADS
	if (dpy->lock && dpy->lock->reply_awaiters) {
	    read_buf = (char *)dpy->lock->reply_awaiters->buf;
	    len = SIZEOF(xReply);
	} else
#endif /* XTHREADS*/
	{
	    read_buf = buf.buf;

	    if (len < SIZEOF(xReply)
#ifdef XTHREADS
		|| dpy->async_handlers
#endif
		)
		len = SIZEOF(xReply);
	    else if (len > BUFSIZE)
		len = BUFSIZE;
	    len = (len / SIZEOF(xReply)) * SIZEOF(xReply);
	}
#ifdef XCONN_CHECK_FREQ
	dpy->conn_checker = 0;
#endif

	(void) _XRead (dpy, read_buf, (long) len);

#ifdef NX_TRANS_SOCKET
        if (_XGetIOError(dpy)) {
            return(dpy->qlen);
        }
#endif
#ifdef XTHREADS
	/* what did we actually read: reply or event? */
	if (dpy->lock && dpy->lock->reply_awaiters) {
	    if (((xReply *)read_buf)->generic.type == X_Reply ||
		((xReply *)read_buf)->generic.type == X_Error)
	    {
		dpy->lock->reply_was_read = True;
		dpy->lock->reply_first = True;
		if (read_buf != (char *)dpy->lock->reply_awaiters->buf)
		    memcpy(dpy->lock->reply_awaiters->buf, read_buf,
			   len);
		if (cvl) {
		    UnlockNextEventReader(dpy);
		}
		return(dpy->qlen); /* we read, so we can return */
	    } else if (read_buf != buf.buf)
		memcpy(buf.buf, read_buf, len);
	}
#endif /* XTHREADS*/

	STARTITERATE(rep,xReply,buf.buf,len > 0) {
	    if (rep->generic.type == X_Reply) {
                int tmp = len;
		RESETITERPTR(rep,xReply,
			     _XAsyncReply (dpy, rep,
					   ITERPTR(rep), &tmp, True));
                len = tmp;
		pend = len;
	    } else {
		if (rep->generic.type == X_Error)
		    _XError (dpy, (xError *)rep);
		else   /* must be an event packet */
		    _XEnq (dpy, (xEvent *)rep);
		INCITERPTR(rep,xReply);
		len -= SIZEOF(xReply);
	    }
	} ENDITERATE

#ifdef XTHREADS
	if (cvl)
#endif
	{
	    UnlockNextEventReader(dpy);
	}
	return(dpy->qlen);
}

/* _XReadEvents - Flush the output queue,
 * then read as many events as possible (but at least 1) and enqueue them
 */
void _XReadEvents(
	register Display *dpy)
{
	_XAlignedBuffer buf;
	BytesReadable_t pend;
	int len;
	register xReply *rep;
	Bool not_yet_flushed = True;
	char *read_buf;
	int i;
	int entry_event_serial_num = dpy->next_event_serial_num;
#ifdef XTHREADS
	struct _XCVList *cvl = NULL;
	xthread_t self;

#ifdef XTHREADS_DEBUG
	printf("_XReadEvents called in thread %x\n",
	       XThread_Self());
#endif
	/* create our condition variable and append to list,
	 * unless we were called from within XProcessInternalConnection
	 * or XLockDisplay
	 */
	xthread_clear_id(self);
	if (dpy->lock && (xthread_have_id (dpy->lock->conni_thread)
			  || xthread_have_id (dpy->lock->locking_thread)))
	    /* some thread is in XProcessInternalConnection or XLockDisplay
	       so we have to see if we are it */
	    self = XThread_Self();
	if (!xthread_have_id(self)
	    || (!xthread_equal(self, dpy->lock->conni_thread)
		&& !xthread_equal(self, dpy->lock->locking_thread)))
	    cvl = QueueEventReaderLock(dpy);
#endif /* XTHREADS */

	do {
#ifdef XTHREADS
	    /* if it is not our turn to read an event off the wire,
	       wait til we're at head of list */
	    if (dpy->lock && cvl &&
		(dpy->lock->event_awaiters != cvl ||
		 dpy->lock->reply_first)) {
		ConditionWait(dpy, cvl->cv);
		continue;
	    }
#endif /* XTHREADS */
	    /* find out how much data can be read */
	    if (_X11TransBytesReadable(dpy->trans_conn, &pend) < 0)
            {
                _XIOError(dpy);
#ifdef NX_TRANS_SOCKET
                return;
#endif
            }
	    len = pend;

	    /* must read at least one xEvent; if none is pending, then
	       we'll just flush and block waiting for it */
	    if (len < SIZEOF(xEvent)
#ifdef XTHREADS
		|| dpy->async_handlers
#endif
		) {
	    	len = SIZEOF(xEvent);
		/* don't flush until the first time we would block */
		if (not_yet_flushed) {
		    _XFlush (dpy);
		    if (_XNewerQueuedEvent(dpy, entry_event_serial_num)) {
			/* _XReply has read an event for us */
			goto got_event;
		    }
		    not_yet_flushed = False;
		}
	    }

#ifdef XTHREADS
	    /* If someone is waiting for a reply, gamble that
	       the reply will be the next thing on the wire
	       and read it into their buffer. */
	    if (dpy->lock && dpy->lock->reply_awaiters) {
		read_buf = (char *)dpy->lock->reply_awaiters->buf;
		len = SIZEOF(xReply);
	    } else
#endif /* XTHREADS*/
	    {
		read_buf = buf.buf;

		/* but we won't read more than the max buffer size */
		if (len > BUFSIZE)
		    len = BUFSIZE;

		/* round down to an integral number of XReps */
		len = (len / SIZEOF(xEvent)) * SIZEOF(xEvent);
	    }

#ifdef XTHREADS
	    if (xthread_have_id(self))
		/* save value we may have to stick in conni_thread */
		dpy->lock->reading_thread = self;
#endif /* XTHREADS */
	    dpy->flags |= XlibDisplayReadEvents;
	    i = _XRead (dpy, read_buf, (long) len);
	    dpy->flags &= ~XlibDisplayReadEvents;
#ifdef NX_TRANS_SOCKET
            if (dpy->flags & XlibDisplayIOError)
            {
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
                fprintf(stderr, "_XReadEvents: Returning with I/O error detected.\n");
#endif
                return;
            }
#endif
	    if (i == -2) {
		/* special flag from _XRead to say that internal connection has
		   done XPutBackEvent.  Which we can use so we're done. */
	      got_event:
#ifdef XTHREADS
		if (dpy->lock && dpy->lock->lock_wait) {
		    if (dpy->lock->event_awaiters != cvl)
			/* since it is not us, must be user lock thread */
			ConditionSignal(dpy,
					dpy->lock->event_awaiters->cv);
		    (*dpy->lock->lock_wait)(dpy);
		    continue;
		}
#endif
		break;
	    }
#ifdef XTHREADS
	    if (xthread_have_id(self))
		xthread_clear_id(dpy->lock->reading_thread);

	    /* what did we actually read: reply or event? */
	    if (dpy->lock && dpy->lock->reply_awaiters) {
		if (((xReply *)read_buf)->generic.type == X_Reply ||
		    ((xReply *)read_buf)->generic.type == X_Error)
		{
		    dpy->lock->reply_was_read = True;
		    dpy->lock->reply_first = True;
		    if (read_buf != (char *)dpy->lock->reply_awaiters->buf)
			memcpy(dpy->lock->reply_awaiters->buf,
			       read_buf, len);
		    ConditionSignal(dpy, dpy->lock->reply_awaiters->cv);
		    continue;
		} else if (read_buf != buf.buf)
		    memcpy(buf.buf, read_buf, len);
	    }
#endif /* XTHREADS */

	    STARTITERATE(rep,xReply,buf.buf,len > 0) {
		if (rep->generic.type == X_Reply) {
		    RESETITERPTR(rep,xReply,
				 _XAsyncReply (dpy, rep,
					       ITERPTR(rep), &len, True));
		    pend = len;
		} else {
		    if (rep->generic.type == X_Error)
			_XError (dpy, (xError *) rep);
		    else   /* must be an event packet */
                    {
                        if (rep->generic.type == GenericEvent)
                        {
                            int evlen;
                            evlen = (rep->generic.length << 2);
                            if (_XRead(dpy, &read_buf[len], evlen) == -2)
                                goto got_event; /* XXX: aargh! */
                        }

                        _XEnq (dpy, (xEvent *)rep);
                    }
		    INCITERPTR(rep,xReply);
		    len -= SIZEOF(xReply);
		}
	    } ENDITERATE;
	} while (!_XNewerQueuedEvent(dpy, entry_event_serial_num));

	UnlockNextEventReader(dpy);
}

/*
 * _XRead - Read bytes from the socket taking into account incomplete
 * reads.  This routine may have to be reworked if int < long.
 */
int _XRead(
	register Display *dpy,
	register char *data,
	register long size)
{
	register long bytes_read;
#ifdef XTHREADS
	int original_size = size;
#endif
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        int congestion;
#endif

	if ((dpy->flags & XlibDisplayIOError) || size == 0)
	    return 0;
	ESET(0);
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        while (1) {
                /*
                 * Need to check the congestion state
                 * after the read so split the statement
                 * in multiple blocks.
                 */

                bytes_read = _X11TransRead(dpy->trans_conn, data, (int)size);
                if (_NXDisplayCongestionFunction != NULL &&
                        _X11TransSocketCongestionChange(dpy->trans_conn, &congestion) == 1) {
                    (*_NXDisplayCongestionFunction)(dpy, congestion);
                }
                if (bytes_read == size) {
                    break;
                }
#else
	while ((bytes_read = _X11TransRead(dpy->trans_conn, data, (int)size))
		!= size) {
#endif

	    	if (bytes_read > 0) {
		    size -= bytes_read;
		    data += bytes_read;
		    }
		else if (ETEST()) {
		    if (_XWaitForReadable(dpy) == -2)
			return -2; /* internal connection did XPutBackEvent */
		    ESET(0);
		}
#ifdef SUNSYSV
		else if (ECHECK(0)) {
		    if (_XWaitForReadable(dpy) == -2)
			return -2; /* internal connection did XPutBackEvent */
		}
#endif
		else if (bytes_read == 0) {
		    /* Read failed because of end of file! */
		    ESET(EPIPE);
#ifdef NX_TRANS_SOCKET
                    _XIOError(dpy);

                    return -1;
#else
		    _XIOError(dpy);
#endif
		    }

		else  /* bytes_read is less than 0; presumably -1 */ {
		    /* If it's a system call interrupt, it's not an error. */
#ifdef NX_TRANS_SOCKET
                    if (!ECHECK(EINTR) ||
                        (_NXDisplayErrorFunction != NULL &&
                            (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                        _XIOError(dpy);
                        return -1;
                    }
#else
		    if (!ECHECK(EINTR))
		    	_XIOError(dpy);
#endif
		    }
#ifdef NX_TRANS_SOCKET
                if (_XGetIOError(dpy)) {
                    return -1;
                }
#endif
	    	 }
#ifdef XTHREADS
       if (dpy->lock && dpy->lock->reply_bytes_left > 0)
       {
           dpy->lock->reply_bytes_left -= original_size;
           if (dpy->lock->reply_bytes_left == 0) {
	       dpy->flags &= ~XlibDisplayReply;
               UnlockNextReplyReader(dpy);
	   }
       }
#endif /* XTHREADS*/
	return 0;
}
#endif /* !USE_XCB */

#ifdef LONG64
void _XRead32(
    Display *dpy,
    register long *data,
    long len)
{
    register int *buf;
    register long i;

    if (len) {
	(void) _XRead(dpy, (char *)data, len);
	i = len >> 2;
	buf = (int *)data + i;
	data += i;
	while (--i >= 0)
	    *--data = *--buf;
    }
}
#endif /* LONG64 */



#if !USE_XCB
/*
 * _XReadPad - Read bytes from the socket taking into account incomplete
 * reads.  If the number of bytes is not 0 mod 4, read additional pad
 * bytes. This routine may have to be reworked if int < long.
 */
void _XReadPad(
    	register Display *dpy,
	register char *data,
	register long size)
{
    	register long bytes_read;
	struct iovec iov[2];
	char pad[3];
#ifdef XTHREADS
        int original_size;
#endif
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        int congestion;
#endif

	if ((dpy->flags & XlibDisplayIOError) || size == 0) return;
	iov[0].iov_len = (int)size;
	iov[0].iov_base = data;
	/*
	 * The following hack is used to provide 32 bit long-word
	 * aligned padding.  The [1] vector is of length 0, 1, 2, or 3,
	 * whatever is needed.
	 */

	iov[1].iov_len = -size & 3;
	iov[1].iov_base = pad;
	size += iov[1].iov_len;
#ifdef XTHREADS
	original_size = size;
#endif
	ESET(0);
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        while (1) {
            bytes_read = _X11TransReadv (dpy->trans_conn, iov, 2);
            if (_NXDisplayCongestionFunction != NULL &&
                    _X11TransSocketCongestionChange(dpy->trans_conn, &congestion) == 1) {
                (*_NXDisplayCongestionFunction)(dpy, congestion);
            }
            if (bytes_read == size) {
                break;
            }
#else
	while ((bytes_read = _X11TransReadv (dpy->trans_conn, iov, 2)) != size) {
#endif

	    if (bytes_read > 0) {
		size -= bytes_read;
		if (iov[0].iov_len < bytes_read) {
		    int pad_bytes_read = bytes_read - iov[0].iov_len;
		    iov[1].iov_len -= pad_bytes_read;
		    iov[1].iov_base =
			(char *)iov[1].iov_base + pad_bytes_read;
		    iov[0].iov_len = 0;
		    }
	    	else {
		    iov[0].iov_len -= bytes_read;
	    	    iov[0].iov_base = (char *)iov[0].iov_base + bytes_read;
	    	}
	    }
	    else if (ETEST()) {
		_XWaitForReadable(dpy);
		ESET(0);
	    }
#ifdef SUNSYSV
	    else if (ECHECK(0)) {
		_XWaitForReadable(dpy);
	    }
#endif
	    else if (bytes_read == 0) {
		/* Read failed because of end of file! */
		ESET(EPIPE);
#ifdef NX_TRANS_SOCKET
                _XIOError(dpy);

                return;
#else
		_XIOError(dpy);
#endif
		}

	    else  /* bytes_read is less than 0; presumably -1 */ {
		/* If it's a system call interrupt, it's not an error. */
#ifdef NX_TRANS_SOCKET
		if (!ECHECK(EINTR) ||
                        (_NXDisplayErrorFunction != NULL &&
                            (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                    _XIOError(dpy);
                    return;
                }
#else
		if (!ECHECK(EINTR))
		    _XIOError(dpy);
#endif
		}
#ifdef NX_TRANS_SOCKET
            if (_XGetIOError(dpy)) {
                return;
            }
#endif
	    }
#ifdef XTHREADS
       if (dpy->lock && dpy->lock->reply_bytes_left > 0)
       {
           dpy->lock->reply_bytes_left -= original_size;
           if (dpy->lock->reply_bytes_left == 0) {
	       dpy->flags &= ~XlibDisplayReply;
               UnlockNextReplyReader(dpy);
	   }
       }
#endif /* XTHREADS*/
}

/*
 * _XSend - Flush the buffer and send the client data. 32 bit word aligned
 * transmission is used, if size is not 0 mod 4, extra bytes are transmitted.
 * This routine may have to be reworked if int < long;
 */
void
_XSend (
	register Display *dpy,
	_Xconst char *data,
	register long size)
{
	struct iovec iov[3];
	static char const pad[3] = {0, 0, 0};
           /* XText8 and XText16 require that the padding bytes be zero! */

	long skip, dbufsize, padsize, total, todo;
	_XExtension *ext;
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_CHANGE)
        int congestion;
#endif

#ifdef NX_TRANS_SOCKET
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "_XSend: Sending data with [%d] bytes to write.\n",
                (dpy->bufptr - dpy->buffer));
#endif
        if (!size || (dpy->flags & XlibDisplayIOError))
        {
            if (dpy->flags & XlibDisplayIOError)
            {
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
                fprintf(stderr, "_XSend: Returning with I/O error detected.\n");
#endif
	        dpy->bufptr = dpy->buffer;
	        dpy->last_req = (char *)&_dummy_request;
            }

	    return;
	}
#else
	if (!size || (dpy->flags & XlibDisplayIOError)) return;
#endif
	dbufsize = dpy->bufptr - dpy->buffer;
#ifdef XTHREADS
	dpy->flags |= XlibDisplayWriting;
	/* make sure no one else can put in data */
	dpy->bufptr = dpy->bufmax;
#endif
	padsize = -size & 3;
	for (ext = dpy->flushes; ext; ext = ext->next_flush) {
	    (*ext->before_flush)(dpy, &ext->codes, dpy->buffer, dbufsize);
	    (*ext->before_flush)(dpy, &ext->codes, (char *)data, size);
	    if (padsize)
		(*ext->before_flush)(dpy, &ext->codes, pad, padsize);
	}
	skip = 0;
	todo = total = dbufsize + size + padsize;

	/*
	 * There are 3 pieces that may need to be written out:
	 *
	 *     o  whatever is in the display buffer
	 *     o  the data passed in by the user
	 *     o  any padding needed to 32bit align the whole mess
	 *
	 * This loop looks at all 3 pieces each time through.  It uses skip
	 * to figure out whether or not a given piece is needed.
	 */
	while (total) {
	    long before = skip;		/* amount of whole thing written */
	    long remain = todo;		/* amount to try this time, <= total */
	    int i = 0;
	    long len;

	    /* You could be very general here and have "in" and "out" iovecs
	     * and write a loop without using a macro, but what the heck.  This
	     * translates to:
	     *
	     *     how much of this piece is new?
	     *     if more new then we are trying this time, clamp
	     *     if nothing new
	     *         then bump down amount already written, for next piece
	     *         else put new stuff in iovec, will need all of next piece
	     *
	     * Note that todo had better be at least 1 or else we'll end up
	     * writing 0 iovecs.
	     */
#define InsertIOV(pointer, length) \
	    len = (length) - before; \
	    if (len > remain) \
		len = remain; \
	    if (len <= 0) { \
		before = (-len); \
	    } else { \
		iov[i].iov_len = len; \
		iov[i].iov_base = (pointer) + before; \
		i++; \
		remain -= len; \
		before = 0; \
	    }

	    InsertIOV (dpy->buffer, dbufsize)
	    InsertIOV ((char *)data, size)
	    InsertIOV ((char *)pad, padsize)

	    ESET(0);
	    if ((len = _X11TransWritev(dpy->trans_conn, iov, i)) >= 0) {
#ifdef NX_TRANS_SOCKET
                if (_NXDisplayWriteFunction != NULL) {
                    (*_NXDisplayWriteFunction)(dpy, len);
                }
#ifdef NX_TRANS_CHANGE
                if (_NXDisplayCongestionFunction != NULL &&
                        _X11TransSocketCongestionChange(dpy->trans_conn, &congestion) == 1) {
                    (*_NXDisplayCongestionFunction)(dpy, congestion);
                }
#endif
#endif
		skip += len;
		total -= len;
		todo = total;
	    } else if (ETEST()) {
		_XWaitForWritable(dpy
#ifdef XTHREADS
				  , NULL
#endif
				  );
#ifdef SUNSYSV
	    } else if (ECHECK(0)) {
		_XWaitForWritable(dpy
#ifdef XTHREADS
				  , NULL
#endif
				  );
#endif
#ifdef ESZTEST
	    } else if (ESZTEST()) {
		if (todo > 1)
		  todo >>= 1;
		else {
		    _XWaitForWritable(dpy
#ifdef XTHREADS
				      , NULL
#endif
				      );
		}
#endif
#ifdef NX_TRANS_SOCKET
            } else if (!ECHECK(EINTR) ||
                (_NXDisplayErrorFunction != NULL &&
                    (*_NXDisplayErrorFunction)(dpy, _XGetIOError(dpy)))) {
                _XIOError(dpy);
                return;
            }
#else
	    } else if (!ECHECK(EINTR)) {
		_XIOError(dpy);
	    }
#endif
#ifdef NX_TRANS_SOCKET
            if (_XGetIOError(dpy)) {
                return;
            }
#endif
	}
	dpy->last_req = (char *) & _dummy_request;
	_XSetSeqSyncFunction(dpy);
	dpy->bufptr = dpy->buffer;
#ifdef XTHREADS
	dpy->flags &= ~XlibDisplayWriting;
#endif
	return;
}

static void
_XGetMiscCode(
    register Display *dpy)
{
    xQueryExtensionReply qrep;
    register xQueryExtensionReq *qreq;
    xXCMiscGetVersionReply vrep;
    register xXCMiscGetVersionReq *vreq;

    if (dpy->xcmisc_opcode)
	return;
    GetReq(QueryExtension, qreq);
    qreq->nbytes = sizeof(XCMiscExtensionName) - 1;
    qreq->length += (qreq->nbytes+(unsigned)3)>>2;
    _XSend(dpy, XCMiscExtensionName, (long)qreq->nbytes);
    if (!_XReply (dpy, (xReply *)&qrep, 0, xTrue))
	dpy->xcmisc_opcode = -1;
    else {
	GetReq(XCMiscGetVersion, vreq);
	vreq->reqType = qrep.major_opcode;
	vreq->miscReqType = X_XCMiscGetVersion;
	vreq->majorVersion = XCMiscMajorVersion;
	vreq->minorVersion = XCMiscMinorVersion;
	if (!_XReply (dpy, (xReply *)&vrep, 0, xTrue))
	    dpy->xcmisc_opcode = -1;
	else
	    dpy->xcmisc_opcode = qrep.major_opcode;
    }
}

void
_XIDHandler(
    register Display *dpy)
{
    xXCMiscGetXIDRangeReply grep;
    register xXCMiscGetXIDRangeReq *greq;

    if (dpy->resource_max == dpy->resource_mask + 1) {
	_XGetMiscCode(dpy);
	if (dpy->xcmisc_opcode > 0) {
	    GetReq(XCMiscGetXIDRange, greq);
	    greq->reqType = dpy->xcmisc_opcode;
	    greq->miscReqType = X_XCMiscGetXIDRange;
	    if (_XReply (dpy, (xReply *)&grep, 0, xTrue) && grep.count) {
		dpy->resource_id = ((grep.start_id - dpy->resource_base) >>
				    dpy->resource_shift);
		dpy->resource_max = dpy->resource_id;
		if (grep.count > 5)
		    dpy->resource_max += grep.count - 6;
		dpy->resource_max <<= dpy->resource_shift;
	    }
	    sync_while_locked(dpy);
	}
    }
}

/*
 * _XAllocID - resource ID allocation routine.
 */
XID _XAllocID(
    register Display *dpy)
{
   XID id;

   id = dpy->resource_id << dpy->resource_shift;
   if (id >= dpy->resource_max) {
	_XSetPrivSyncFunction(dpy);
       dpy->resource_max = dpy->resource_mask + 1;
   }
   if (id <= dpy->resource_mask) {
       dpy->resource_id++;
       return (dpy->resource_base + id);
   }
   if (id != 0x10000000) {
       (void) fprintf(stderr,
		      "Xlib: resource ID allocation space exhausted!\n");
       id = 0x10000000;
       dpy->resource_id = id >> dpy->resource_shift;
   }
   return id;
}

/*
 * _XAllocIDs - multiple resource ID allocation routine.
 */
void _XAllocIDs(
    register Display *dpy,
    XID *ids,
    int count)
{
    XID id;
    int i;
    xXCMiscGetXIDListReply grep;
    register xXCMiscGetXIDListReq *greq;

    id = dpy->resource_id << dpy->resource_shift;
    if (dpy->resource_max <= dpy->resource_mask &&
	id <= dpy->resource_mask &&
	(dpy->resource_max - id) > ((count - 1) << dpy->resource_shift)) {
	id += dpy->resource_base;
	for (i = 0; i < count; i++) {
	    ids[i] = id;
	    id += (1 << dpy->resource_shift);
	    dpy->resource_id++;
	}
	return;
    }
    grep.count = 0;
    _XGetMiscCode(dpy);
    if (dpy->xcmisc_opcode > 0) {
	GetReq(XCMiscGetXIDList, greq);
	greq->reqType = dpy->xcmisc_opcode;
	greq->miscReqType = X_XCMiscGetXIDList;
	greq->count = count;
	if (_XReply(dpy, (xReply *)&grep, 0, xFalse) && grep.count) {
	    _XRead32(dpy, (long *) ids, 4L * (long) (grep.count));
	    for (i = 0; i < grep.count; i++) {
		id = (ids[i] - dpy->resource_base) >> dpy->resource_shift;
		if (id >= dpy->resource_id)
		    dpy->resource_id = id;
	    }
	    if (id >= dpy->resource_max) {
		_XSetPrivSyncFunction(dpy);
		dpy->resource_max = dpy->resource_mask + 1;
	    }
	}
    }
    for (i = grep.count; i < count; i++)
	ids[i] = XAllocID(dpy);
}
#endif /* !USE_XCB */

/*
 * The hard part about this is that we only get 16 bits from a reply.
 * We have three values that will march along, with the following invariant:
 *	dpy->last_request_read <= rep->sequenceNumber <= dpy->request
 * We have to keep
 *	dpy->request - dpy->last_request_read < 2^16
 * or else we won't know for sure what value to use in events.  We do this
 * by forcing syncs when we get close.
 */

unsigned long
_XSetLastRequestRead(
    register Display *dpy,
    register xGenericReply *rep)
{
    register uint64_t	newseq, lastseq;

    lastseq = X_DPY_GET_LAST_REQUEST_READ(dpy);
    /*
     * KeymapNotify has no sequence number, but is always guaranteed
     * to immediately follow another event, except when generated via
     * SendEvent (hmmm).
     */
    if ((rep->type & 0x7f) == KeymapNotify)
	return(lastseq);

    newseq = (lastseq & ~((uint64_t)0xffff)) | rep->sequenceNumber;

    if (newseq < lastseq) {
	newseq += 0x10000;
	if (newseq > X_DPY_GET_REQUEST(dpy)) {
#ifdef NX_TRANS_SOCKET
	    if (_NXLostSequenceFunction != NULL)
	    {
		(*_NXLostSequenceFunction)(dpy, newseq, X_DPY_GET_REQUEST(dpy),
					       (unsigned int) rep->type);
	    }
	    else
#endif /* #ifdef NX_TRANS_SOCKET */
	    {
		(void) fprintf (stderr,
				"Xlib: sequence lost (0x%llx > 0x%llx) in reply type 0x%x!\n",
				(unsigned long long)newseq,
				(unsigned long long)(X_DPY_GET_REQUEST(dpy)),
				(unsigned int) rep->type);
	    }
	    newseq -= 0x10000;
	}
    }

    X_DPY_SET_LAST_REQUEST_READ(dpy, newseq);
    return(newseq);
}

#if !USE_XCB
/*
 * _XReply - Wait for a reply packet and copy its contents into the
 * specified rep.  Meanwhile we must handle error and event packets that
 * we may encounter.
 */
Status
_XReply (
    register Display *dpy,
    register xReply *rep,
    int extra,		/* number of 32-bit words expected after the reply */
    Bool discard)	/* should I discard data following "extra" words? */
{
    /* Pull out the serial number now, so that (currently illegal) requests
     * generated by an error handler don't confuse us.
     */
    unsigned long cur_request = dpy->request;
#ifdef XTHREADS
    struct _XCVList *cvl;
#endif
#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "_XReply: Going to wait for an X reply.\n");
#endif

#ifdef NX_TRANS_SOCKET
    if (dpy->flags & XlibDisplayIOError)
    {
#ifdef NX_TRANS_DEBUG
        fprintf(stderr, "_XReply: Returning 0 with I/O error detected.\n");
#endif
        return 0;
    }
#else
    if (dpy->flags & XlibDisplayIOError)
	return 0;
#endif

#ifdef XTHREADS
    /* create our condition variable and append to list */
    cvl = QueueReplyReaderLock(dpy);
    if (cvl) {
	cvl->buf = rep;
	if (dpy->lock->reply_awaiters == cvl && !dpy->lock->event_awaiters)
	    dpy->lock->reply_first = True;
    }

#ifdef XTHREADS_DEBUG
    printf("_XReply called in thread %x, adding %x to cvl\n",
	   XThread_Self(), cvl);
#endif

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "_XReply: Going to flush the display buffer.\n");
#endif
    _XFlushInt(dpy, cvl ? cvl->cv : NULL);
    /* if it is not our turn to read a reply off the wire,
     * wait til we're at head of list.  if there is an event waiter,
     * and our reply hasn't been read, they'll be in select and will
     * hand control back to us next.
     */
    if(dpy->lock &&
       (dpy->lock->reply_awaiters != cvl || !dpy->lock->reply_first)) {
	ConditionWait(dpy, cvl->cv);
    }
    dpy->flags |= XlibDisplayReply;
#else /* XTHREADS else */
    _XFlush(dpy);
#endif

#ifdef NX_TRANS_SOCKET
    /*
     * We are going to block waiting for the remote
     * X server. Be sure that the proxy has flushed
     * all the data.
     */

#ifdef NX_TRANS_TEST
    fprintf(stderr, "_XReply: Requesting a flush of the NX transport.\n");
#endif
    NXTransFlush(dpy->fd);
#endif

    for (;;) {
#ifdef XTHREADS
	/* Did another thread's _XReadEvents get our reply by accident? */
	if (!dpy->lock || !dpy->lock->reply_was_read)
#endif
	    (void) _XRead(dpy, (char *)rep, (long)SIZEOF(xReply));
#ifdef XTHREADS
	if (dpy->lock)
	    dpy->lock->reply_was_read = False;
#endif

	switch ((int)rep->generic.type) {

	    case X_Reply:
	        /* Reply received.  Fast update for synchronous replies,
		 * but deal with multiple outstanding replies.
		 */
	        if (rep->generic.sequenceNumber == (cur_request & 0xffff))
		    dpy->last_request_read = cur_request;
		else {
		    int pend = SIZEOF(xReply);
		    if (_XAsyncReply(dpy, rep, (char *)rep, &pend, False)
			!= (char *)rep)
			continue;
		}
		if (extra <= rep->generic.length) {
		    if (extra > 0)
			/*
			 * Read the extra data into storage immediately
			 * following the GenericReply structure.
			 */
			(void) _XRead (dpy, (char *) (NEXTPTR(rep,xReply)),
				((long)extra) << 2);
		    if (discard) {
			if (extra < rep->generic.length)
			    _XEatData(dpy, (rep->generic.length - extra) << 2);
		    }
#ifdef XTHREADS
		    if (dpy->lock) {
			if (discard) {
			    dpy->lock->reply_bytes_left = 0;
			} else {
			    dpy->lock->reply_bytes_left =
				(rep->generic.length - extra) << 2;
			}
			if (dpy->lock->reply_bytes_left == 0) {
			    dpy->flags &= ~XlibDisplayReply;
			    UnlockNextReplyReader(dpy);
			}
		    } else
			dpy->flags &= ~XlibDisplayReply;
#endif
		    return 1;
		}
		/*
		 *if we get here, then extra > rep->generic.length--meaning we
		 * read a reply that's shorter than we expected.  This is an
		 * error,  but we still need to figure out how to handle it...
		 */
		(void) _XRead (dpy, (char *) (NEXTPTR(rep,xReply)),
			((long) rep->generic.length) << 2);
		dpy->flags &= ~XlibDisplayReply;
		UnlockNextReplyReader(dpy);
#ifdef NX_TRANS_SOCKET
                /*
                 * The original code has provision
                 * for returning already.
                 */
#endif
		_XIOError (dpy);
		return (0);

    	    case X_Error:
	    	{
	        register _XExtension *ext;
		register Bool ret = False;
		int ret_code;
		xError *err = (xError *) rep;
		unsigned long serial;

		dpy->flags &= ~XlibDisplayReply;
		serial = _XSetLastRequestRead(dpy, (xGenericReply *)rep);
		if (serial == cur_request)
			/* do not die on "no such font", "can't allocate",
			   "can't grab" failures */
			switch ((int)err->errorCode) {
			case BadName:
			    switch (err->majorCode) {
				case X_LookupColor:
				case X_AllocNamedColor:
				    UnlockNextReplyReader(dpy);
				    return(0);
			    }
			    break;
			case BadFont:
			    if (err->majorCode == X_QueryFont) {
				UnlockNextReplyReader(dpy);
				return (0);
			    }
			    break;
			case BadAlloc:
			case BadAccess:
			    UnlockNextReplyReader(dpy);
			    return (0);
			}
		/*
		 * we better see if there is an extension who may
		 * want to suppress the error.
		 */
		for (ext = dpy->ext_procs; !ret && ext; ext = ext->next) {
		    if (ext->error)
		       ret = (*ext->error)(dpy, err, &ext->codes, &ret_code);
		}
		if (!ret) {
		    _XError(dpy, err);
		    ret_code = 0;
		}
		if (serial == cur_request) {
		    UnlockNextReplyReader(dpy);
		    return(ret_code);
		}

		} /* case X_Error */
		break;
	    default:
		_XEnq(dpy, (xEvent *) rep);
#ifdef XTHREADS
		if (dpy->lock && dpy->lock->event_awaiters)
		    ConditionSignal(dpy, dpy->lock->event_awaiters->cv);
#endif
		break;
	    }
#ifdef NX_TRANS_SOCKET
            if (_XGetIOError(dpy)) {
                UnlockNextReplyReader(dpy);
                return 0;
            }
#endif
	}
}

static char *
_XAsyncReply(
    Display *dpy,
    register xReply *rep,
    char *buf,
    register int *lenp,
    Bool discard)
{
    register _XAsyncHandler *async, *next;
    register int len;
    register Bool consumed = False;
    char *nbuf;

    (void) _XSetLastRequestRead(dpy, &rep->generic);
    len = SIZEOF(xReply) + (rep->generic.length << 2);
    if (len < SIZEOF(xReply)) {
#ifdef NX_TRANS_SOCKET

        /*
         * The original code has provision
         * for returning already.
         */

#endif
	_XIOError (dpy);
	buf += *lenp;
	*lenp = 0;
	return buf;
    }

    for (async = dpy->async_handlers; async; async = next) {
	next = async->next;
	if ((consumed = (*async->handler)(dpy, rep, buf, *lenp, async->data)))
	    break;
    }
    if (!consumed) {
	if (!discard)
	    return buf;
	(void) fprintf(stderr,
		       "Xlib: unexpected async reply (sequence 0x%lx)!\n",
		       dpy->last_request_read);
#ifdef XTHREADS
#ifdef XTHREADS_DEBUG
	printf("thread %x, unexpected async reply\n", XThread_Self());
#endif
#endif
	if (len > *lenp)
	    _XEatData(dpy, len - *lenp);
    }
    if (len < SIZEOF(xReply))
    {
#ifdef NX_TRANS_SOCKET

        /*
         * The original code has provision
         * for returning already.
         */

#endif
	_XIOError (dpy);
	buf += *lenp;
	*lenp = 0;
	return buf;
    }
    if (len >= *lenp) {
	buf += *lenp;
	*lenp = 0;
	return buf;
    }
    *lenp -= len;
    buf += len;
    len = *lenp;
    nbuf = buf;
    while (len > SIZEOF(xReply)) {
	if (*buf == X_Reply)
	    return nbuf;
	buf += SIZEOF(xReply);
	len -= SIZEOF(xReply);
    }
    if (len > 0 && len < SIZEOF(xReply)) {
	buf = nbuf;
	len = SIZEOF(xReply) - len;
	nbuf -= len;
	memmove(nbuf, buf, *lenp);
	(void) _XRead(dpy, nbuf + *lenp, (long)len);
	*lenp += len;
    }
    return nbuf;
}
#endif /* !USE_XCB */

/*
 * Support for internal connections, such as an IM might use.
 * By Stephen Gildea, X Consortium, September 1993
 */

/* _XRegisterInternalConnection
 * Each IM (or Xlib extension) that opens a file descriptor that Xlib should
 * include in its select/poll mask must call this function to register the
 * fd with Xlib.  Any XConnectionWatchProc registered by XAddConnectionWatch
 * will also be called.
 *
 * Whenever Xlib detects input available on fd, it will call callback
 * with call_data to process it.  If non-Xlib code calls select/poll
 * and detects input available, it must call XProcessInternalConnection,
 * which will call the associated callback.
 *
 * Non-Xlib code can learn about these additional fds by calling
 * XInternalConnectionNumbers or, more typically, by registering
 * a XConnectionWatchProc with XAddConnectionWatch
 * to be called when fds are registered or unregistered.
 *
 * Returns True if registration succeeded, False if not, typically
 * because could not allocate memory.
 * Assumes Display locked when called.
 */
Status
_XRegisterInternalConnection(
    Display* dpy,
    int fd,
    _XInternalConnectionProc callback,
    XPointer call_data
)
{
    struct _XConnectionInfo *new_conni, **iptr;
    struct _XConnWatchInfo *watchers;
    XPointer *wd;

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "_XRegisterInternalConnection: Got called.\n");
#endif
    new_conni = Xmalloc(sizeof(struct _XConnectionInfo));
    if (!new_conni)
	return 0;
    new_conni->watch_data = Xmalloc(dpy->watcher_count * sizeof(XPointer));
    if (!new_conni->watch_data) {
	Xfree(new_conni);
	return 0;
    }
    new_conni->fd = fd;
    new_conni->read_callback = callback;
    new_conni->call_data = call_data;
    new_conni->next = NULL;
    /* link new structure onto end of list */
    for (iptr = &dpy->im_fd_info; *iptr; iptr = &(*iptr)->next)
	;
    *iptr = new_conni;
    dpy->im_fd_length++;
    _XPollfdCacheAdd(dpy, fd);

    for (watchers=dpy->conn_watchers, wd=new_conni->watch_data;
	 watchers;
	 watchers=watchers->next, wd++) {
	*wd = NULL;		/* for cleanliness */
	(*watchers->fn) (dpy, watchers->client_data, fd, True, wd);
    }

    return 1;
}

/* _XUnregisterInternalConnection
 * Each IM (or Xlib extension) that closes a file descriptor previously
 * registered with _XRegisterInternalConnection must call this function.
 * Any XConnectionWatchProc registered by XAddConnectionWatch
 * will also be called.
 *
 * Assumes Display locked when called.
 */
void
_XUnregisterInternalConnection(
    Display* dpy,
    int fd
)
{
    struct _XConnectionInfo *info_list, **prev;
    struct _XConnWatchInfo *watch;
    XPointer *wd;

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "_XUnregisterInternalConnection: Got called.\n");
#endif
    for (prev = &dpy->im_fd_info; (info_list = *prev);
	 prev = &info_list->next) {
	if (info_list->fd == fd) {
	    *prev = info_list->next;
	    dpy->im_fd_length--;
	    for (watch=dpy->conn_watchers, wd=info_list->watch_data;
		 watch;
		 watch=watch->next, wd++) {
		(*watch->fn) (dpy, watch->client_data, fd, False, wd);
	    }
	    Xfree (info_list->watch_data);
	    Xfree (info_list);
	    break;
	}
    }
    _XPollfdCacheDel(dpy, fd);
}

/* XInternalConnectionNumbers
 * Returns an array of fds and an array of corresponding call data.
 * Typically a XConnectionWatchProc registered with XAddConnectionWatch
 * will be used instead of this function to discover
 * additional fds to include in the select/poll mask.
 *
 * The list is allocated with Xmalloc and should be freed by the caller
 * with Xfree;
 */
Status
XInternalConnectionNumbers(
    Display *dpy,
    int **fd_return,
    int *count_return
)
{
    int count;
    struct _XConnectionInfo *info_list;
    int *fd_list;

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "XInternalConnectionNumbers: Got called.\n");
#endif
    LockDisplay(dpy);
    count = 0;
    for (info_list=dpy->im_fd_info; info_list; info_list=info_list->next)
	count++;
    fd_list = Xmalloc (count * sizeof(int));
    if (!fd_list) {
	UnlockDisplay(dpy);
	return 0;
    }
    count = 0;
    for (info_list=dpy->im_fd_info; info_list; info_list=info_list->next) {
	fd_list[count] = info_list->fd;
	count++;
    }
    UnlockDisplay(dpy);

    *fd_return = fd_list;
    *count_return = count;
    return 1;
}

void _XProcessInternalConnection(
    Display *dpy,
    struct _XConnectionInfo *conn_info)
{
    dpy->flags |= XlibDisplayProcConni;
#if defined(XTHREADS) && !USE_XCB
    if (dpy->lock) {
	/* check cache to avoid call to thread_self */
	if (xthread_have_id(dpy->lock->reading_thread))
	    dpy->lock->conni_thread = dpy->lock->reading_thread;
	else
	    dpy->lock->conni_thread = XThread_Self();
    }
#endif /* XTHREADS && !USE_XCB */
    UnlockDisplay(dpy);
    (*conn_info->read_callback) (dpy, conn_info->fd, conn_info->call_data);
    LockDisplay(dpy);
#if defined(XTHREADS) && !USE_XCB
    if (dpy->lock)
	xthread_clear_id(dpy->lock->conni_thread);
#endif /* XTHREADS && !USE_XCB */
    dpy->flags &= ~XlibDisplayProcConni;
}

/* XProcessInternalConnection
 * Call the _XInternalConnectionProc registered by _XRegisterInternalConnection
 * for this fd.
 * The Display is NOT locked during the call.
 */
void
XProcessInternalConnection(
    Display* dpy,
    int fd
)
{
    struct _XConnectionInfo *info_list;

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "XProcessInternalConnection: Got called.\n");
#endif

    LockDisplay(dpy);
    for (info_list=dpy->im_fd_info; info_list; info_list=info_list->next) {
	if (info_list->fd == fd) {
	    _XProcessInternalConnection(dpy, info_list);
	    break;
	}
    }
    UnlockDisplay(dpy);
}

/* XAddConnectionWatch
 * Register a callback to be called whenever _XRegisterInternalConnection
 * or _XUnregisterInternalConnection is called.
 * Callbacks are called with the Display locked.
 * If any connections are already registered, the callback is immediately
 * called for each of them.
 */
Status
XAddConnectionWatch(
    Display* dpy,
    XConnectionWatchProc callback,
    XPointer client_data
)
{
    struct _XConnWatchInfo *new_watcher, **wptr;
    struct _XConnectionInfo *info_list;
    XPointer *wd_array;

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "XAddConnectionWatch: Got called.\n");
#endif
    LockDisplay(dpy);

    /* allocate new watch data */
    for (info_list=dpy->im_fd_info; info_list; info_list=info_list->next) {
	wd_array = Xrealloc(info_list->watch_data,
			    (dpy->watcher_count + 1) * sizeof(XPointer));
	if (!wd_array) {
	    UnlockDisplay(dpy);
	    return 0;
	}
	info_list->watch_data = wd_array;
	wd_array[dpy->watcher_count] = NULL;	/* for cleanliness */
    }

    new_watcher = Xmalloc(sizeof(struct _XConnWatchInfo));
    if (!new_watcher) {
	UnlockDisplay(dpy);
	return 0;
    }
    new_watcher->fn = callback;
    new_watcher->client_data = client_data;
    new_watcher->next = NULL;

    /* link new structure onto end of list */
    for (wptr = &dpy->conn_watchers; *wptr; wptr = &(*wptr)->next)
	;
    *wptr = new_watcher;
    dpy->watcher_count++;

    /* call new watcher on all currently registered fds */
    for (info_list=dpy->im_fd_info; info_list; info_list=info_list->next) {
	(*callback) (dpy, client_data, info_list->fd, True,
		     info_list->watch_data + dpy->watcher_count - 1);
    }

    UnlockDisplay(dpy);
    return 1;
}

/* XRemoveConnectionWatch
 * Unregister a callback registered by XAddConnectionWatch.
 * Both callback and client_data must match what was passed to
 * XAddConnectionWatch.
 */
void
XRemoveConnectionWatch(
    Display* dpy,
    XConnectionWatchProc callback,
    XPointer client_data
)
{
    struct _XConnWatchInfo *watch;
    struct _XConnWatchInfo *previous = NULL;
    struct _XConnectionInfo *conni;
    int counter = 0;

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "XRemoveConnectionWatch: Got called.\n");
#endif
    LockDisplay(dpy);
    for (watch=dpy->conn_watchers; watch; watch=watch->next) {
	if (watch->fn == callback  &&  watch->client_data == client_data) {
	    if (previous)
		previous->next = watch->next;
	    else
		dpy->conn_watchers = watch->next;
	    Xfree (watch);
	    dpy->watcher_count--;
	    /* remove our watch_data for each connection */
	    for (conni=dpy->im_fd_info; conni; conni=conni->next) {
		/* don't bother realloc'ing; these arrays are small anyway */
		/* overlapping */
		memmove(conni->watch_data+counter,
			conni->watch_data+counter+1,
			dpy->watcher_count - counter);
	    }
	    break;
	}
	previous = watch;
	counter++;
    }
    UnlockDisplay(dpy);
}

/* end of internal connections support */


#if !USE_XCB
/* Read and discard "n" 8-bit bytes of data */

void _XEatData(
    Display *dpy,
    register unsigned long n)
{
#define SCRATCHSIZE 2048
    char buf[SCRATCHSIZE];

#if defined(NX_TRANS_SOCKET) && defined(NX_TRANS_DEBUG)
    fprintf(stderr, "_XEatData: Going to eat [%ld] bytes of data from descriptor [%d].\n",
                n, dpy->fd);
#endif
    while (n > 0) {
	register long bytes_read = (n > SCRATCHSIZE) ? SCRATCHSIZE : n;
	(void) _XRead (dpy, buf, bytes_read);
	n -= bytes_read;
    }
#undef SCRATCHSIZE
}

/*
   Port from libXfixes commit
   b031e3b60fa1af9e49449f23d4a84395868be3ab We need this here to
   enable linking of current libXrender against libNX_X11 instead of
   the system's libX11

   The original implementation of this function (libX11 commit
   9f5d83706543696fc944c1835a403938c06f2cc5) uses xcb stuff which we
   do not have in libNX_X11. So we take a workaround from another
   lib. This workaround had been implemented temporarily in a couple
   of X libs, see e.g. https://lists.x.org/archives/xorg-devel/2013-July/036763.html.
*/
#include <nx-X11/Xmd.h>  /* for LONG64 on 64-bit platforms */
#include <limits.h>

void _XEatDataWords(Display *dpy, unsigned long n)
{
#ifndef LONG64
    if (n >= (ULONG_MAX >> 2))
        _XIOError(dpy);
#endif
    _XEatData (dpy, n << 2);
}
#endif /* !USE_XCB */

/* Cookie jar implementation
   dpy->cookiejar is a linked list. _XEnq receives the events but leaves
   them in the normal EQ. _XStoreEvent returns the cookie event (minus
   data pointer) and adds it to the cookiejar. _XDeq just removes
   the entry like any other event but resets the data pointer for
   cookie events (to avoid double-free, the memory is re-used by Xlib).

   _XFetchEventCookie (called from XGetEventData) removes a cookie from the
   jar. _XFreeEventCookies removes all unclaimed cookies from the jar
   (called by XNextEvent).

   _XFreeDisplayStructure calls _XFreeEventCookies for each cookie in the
   normal EQ.
 */

#include "utlist.h"
struct stored_event {
    XGenericEventCookie ev;
    struct stored_event *prev;
    struct stored_event *next;
};

Bool
_XIsEventCookie(Display *dpy, XEvent *ev)
{
    return (ev->xcookie.type == GenericEvent &&
	    dpy->generic_event_vec[ev->xcookie.extension & 0x7F] != NULL);
}

/**
 * Free all events in the event list.
 */
void
_XFreeEventCookies(Display *dpy)
{
    struct stored_event **head, *e, *tmp;

    if (!dpy->cookiejar)
        return;

    head = (struct stored_event**)&dpy->cookiejar;

    DL_FOREACH_SAFE(*head, e, tmp) {
        if (dpy->cookiejar == e)
            dpy->cookiejar = NULL;
        XFree(e->ev.data);
        XFree(e);
    }
}

/**
 * Add an event to the display's event list. This event must be freed on the
 * next call to XNextEvent().
 */
void
_XStoreEventCookie(Display *dpy, XEvent *event)
{
    XGenericEventCookie* cookie = &event->xcookie;
    struct stored_event **head, *add;

    if (!_XIsEventCookie(dpy, event))
        return;

    head = (struct stored_event**)(&dpy->cookiejar);

    add = Xmalloc(sizeof(struct stored_event));
    if (!add) {
        ESET(ENOMEM);
        _XIOError(dpy);
    }
    add->ev = *cookie;
    DL_APPEND(*head, add);
    cookie->data = NULL; /* don't return data yet, must be claimed */
}

/**
 * Return the event with the given cookie and remove it from the list.
 */
Bool
_XFetchEventCookie(Display *dpy, XGenericEventCookie* ev)
{
    Bool ret = False;
    struct stored_event **head, *event;
    head = (struct stored_event**)&dpy->cookiejar;

    if (!_XIsEventCookie(dpy, (XEvent*)ev))
        return ret;

    DL_FOREACH(*head, event) {
        if (event->ev.cookie == ev->cookie &&
            event->ev.extension == ev->extension &&
            event->ev.evtype == ev->evtype) {
            *ev = event->ev;
            DL_DELETE(*head, event);
            Xfree(event);
            ret = True;
            break;
        }
    }

    return ret;
}

Bool
_XCopyEventCookie(Display *dpy, XGenericEventCookie *in, XGenericEventCookie *out)
{
    Bool ret = False;
    int extension;

    if (!_XIsEventCookie(dpy, (XEvent*)in) || !out)
        return ret;

    extension = in->extension & 0x7F;

    if (!dpy->generic_event_copy_vec[extension])
        return ret;

    ret = ((*dpy->generic_event_copy_vec[extension])(dpy, in, out));
    out->cookie = ret ? ++dpy->next_cookie  : 0;
    return ret;
}


/*
 * _XEnq - Place event packets on the display's queue.
 * note that no squishing of move events in V11, since there
 * is pointer motion hints....
 */
void _XEnq(
	register Display *dpy,
	register xEvent *event)
{
	register _XQEvent *qelt;
	int type, extension;

	if ((qelt = dpy->qfree)) {
		/* If dpy->qfree is non-NULL do this, else malloc a new one. */
		dpy->qfree = qelt->next;
	}
	else if ((qelt = Xmalloc(sizeof(_XQEvent))) == NULL) {
		/* Malloc call failed! */
		ESET(ENOMEM);
                _XIOError(dpy);
#ifdef NX_TRANS_SOCKET
                return;
#endif
	}
	qelt->next = NULL;

	type = event->u.u.type & 0177;
	extension = ((xGenericEvent*)event)->extension;

	qelt->event.type = type;
	/* If an extension has registered a generic_event_vec handler, then
	 * it can handle event cookies. Otherwise, proceed with the normal
	 * event handlers.
	 *
	 * If the generic_event_vec is called, qelt->event is a event cookie
	 * with the data pointer and the "free" pointer set. Data pointer is
	 * some memory allocated by the extension.
	 */
        if (type == GenericEvent && dpy->generic_event_vec[extension & 0x7F]) {
	    XGenericEventCookie *cookie = &qelt->event.xcookie;
	    (*dpy->generic_event_vec[extension & 0x7F])(dpy, cookie, event);
	    cookie->cookie = ++dpy->next_cookie;

	    qelt->qserial_num = dpy->next_event_serial_num++;
	    if (dpy->tail)	dpy->tail->next = qelt;
	    else		dpy->head = qelt;

	    dpy->tail = qelt;
	    dpy->qlen++;
	} else if ((*dpy->event_vec[type])(dpy, &qelt->event, event)) {
	    qelt->qserial_num = dpy->next_event_serial_num++;
	    if (dpy->tail)	dpy->tail->next = qelt;
	    else 		dpy->head = qelt;

	    dpy->tail = qelt;
	    dpy->qlen++;
	} else {
	    /* ignored, or stashed away for many-to-one compression */
	    qelt->next = dpy->qfree;
	    dpy->qfree = qelt;
	}
}

/*
 * _XDeq - Remove event packet from the display's queue.
 */
void _XDeq(
    register Display *dpy,
    register _XQEvent *prev,	/* element before qelt */
    register _XQEvent *qelt)	/* element to be unlinked */
{
    if (prev) {
	if ((prev->next = qelt->next) == NULL)
	    dpy->tail = prev;
    } else {
	/* no prev, so removing first elt */
	if ((dpy->head = qelt->next) == NULL)
	    dpy->tail = NULL;
    }
    qelt->qserial_num = 0;
    qelt->next = dpy->qfree;
    dpy->qfree = qelt;
    dpy->qlen--;

    if (_XIsEventCookie(dpy, &qelt->event)) {
	XGenericEventCookie* cookie = &qelt->event.xcookie;
	/* dpy->qfree is re-used, reset memory to avoid double free on
	 * _XFreeDisplayStructure */
	cookie->data = NULL;
    }
}

/*
 * EventToWire in separate file in that often not needed.
 */

/*ARGSUSED*/
Bool
_XUnknownWireEvent(
    register Display *dpy,	/* pointer to display structure */
    register XEvent *re,	/* pointer to where event should be reformatted */
    register xEvent *event)	/* wire protocol event */
{
#ifdef notdef
	(void) fprintf(stderr,
	    "Xlib: unhandled wire event! event number = %d, display = %x\n.",
			event->u.u.type, dpy);
#endif
	return(False);
}

Bool
_XUnknownWireEventCookie(
    Display *dpy,	/* pointer to display structure */
    XGenericEventCookie *re,	/* pointer to where event should be reformatted */
    xEvent *event)	/* wire protocol event */
{
#ifdef notdef
	fprintf(stderr,
	    "Xlib: unhandled wire cookie event! extension number = %d, display = %x\n.",
			((xGenericEvent*)event)->extension, dpy);
#endif
	return(False);
}

Bool
_XUnknownCopyEventCookie(
    Display *dpy,	/* pointer to display structure */
    XGenericEventCookie *in,	/* source */
    XGenericEventCookie *out)	/* destination */
{
#ifdef notdef
	fprintf(stderr,
	    "Xlib: unhandled cookie event copy! extension number = %d, display = %x\n.",
			in->extension, dpy);
#endif
	return(False);
}

/*ARGSUSED*/
Status
_XUnknownNativeEvent(
    register Display *dpy,	/* pointer to display structure */
    register XEvent *re,	/* pointer to where event should be reformatted */
    register xEvent *event)	/* wire protocol event */
{
#ifdef notdef
	(void) fprintf(stderr,
 	   "Xlib: unhandled native event! event number = %d, display = %x\n.",
			re->type, dpy);
#endif
	return(0);
}
/*
 * reformat a wire event into an XEvent structure of the right type.
 */
Bool
_XWireToEvent(
    register Display *dpy,	/* pointer to display structure */
    register XEvent *re,	/* pointer to where event should be reformatted */
    register xEvent *event)	/* wire protocol event */
{

	re->type = event->u.u.type & 0x7f;
	((XAnyEvent *)re)->serial = _XSetLastRequestRead(dpy,
					(xGenericReply *)event);
	((XAnyEvent *)re)->send_event = ((event->u.u.type & 0x80) != 0);
	((XAnyEvent *)re)->display = dpy;

	/* Ignore the leading bit of the event type since it is set when a
		client sends an event rather than the server. */

	switch (event-> u.u.type & 0177) {
	      case KeyPress:
	      case KeyRelease:
	        {
			register XKeyEvent *ev = (XKeyEvent*) re;
			ev->root 	= event->u.keyButtonPointer.root;
			ev->window 	= event->u.keyButtonPointer.event;
			ev->subwindow 	= event->u.keyButtonPointer.child;
			ev->time 	= event->u.keyButtonPointer.time;
			ev->x 		= cvtINT16toInt(event->u.keyButtonPointer.eventX);
			ev->y 		= cvtINT16toInt(event->u.keyButtonPointer.eventY);
			ev->x_root 	= cvtINT16toInt(event->u.keyButtonPointer.rootX);
			ev->y_root 	= cvtINT16toInt(event->u.keyButtonPointer.rootY);
			ev->state	= event->u.keyButtonPointer.state;
			ev->same_screen	= event->u.keyButtonPointer.sameScreen;
			ev->keycode 	= event->u.u.detail;
		}
	      	break;
	      case ButtonPress:
	      case ButtonRelease:
	        {
			register XButtonEvent *ev =  (XButtonEvent *) re;
			ev->root 	= event->u.keyButtonPointer.root;
			ev->window 	= event->u.keyButtonPointer.event;
			ev->subwindow 	= event->u.keyButtonPointer.child;
			ev->time 	= event->u.keyButtonPointer.time;
			ev->x 		= cvtINT16toInt(event->u.keyButtonPointer.eventX);
			ev->y 		= cvtINT16toInt(event->u.keyButtonPointer.eventY);
			ev->x_root 	= cvtINT16toInt(event->u.keyButtonPointer.rootX);
			ev->y_root 	= cvtINT16toInt(event->u.keyButtonPointer.rootY);
			ev->state	= event->u.keyButtonPointer.state;
			ev->same_screen	= event->u.keyButtonPointer.sameScreen;
			ev->button 	= event->u.u.detail;
		}
	        break;
	      case MotionNotify:
	        {
			register XMotionEvent *ev =   (XMotionEvent *)re;
			ev->root 	= event->u.keyButtonPointer.root;
			ev->window 	= event->u.keyButtonPointer.event;
			ev->subwindow 	= event->u.keyButtonPointer.child;
			ev->time 	= event->u.keyButtonPointer.time;
			ev->x 		= cvtINT16toInt(event->u.keyButtonPointer.eventX);
			ev->y 		= cvtINT16toInt(event->u.keyButtonPointer.eventY);
			ev->x_root 	= cvtINT16toInt(event->u.keyButtonPointer.rootX);
			ev->y_root 	= cvtINT16toInt(event->u.keyButtonPointer.rootY);
			ev->state	= event->u.keyButtonPointer.state;
			ev->same_screen	= event->u.keyButtonPointer.sameScreen;
			ev->is_hint 	= event->u.u.detail;
		}
	        break;
	      case EnterNotify:
	      case LeaveNotify:
		{
			register XCrossingEvent *ev   = (XCrossingEvent *) re;
			ev->root	= event->u.enterLeave.root;
			ev->window	= event->u.enterLeave.event;
			ev->subwindow	= event->u.enterLeave.child;
			ev->time	= event->u.enterLeave.time;
			ev->x		= cvtINT16toInt(event->u.enterLeave.eventX);
			ev->y		= cvtINT16toInt(event->u.enterLeave.eventY);
			ev->x_root	= cvtINT16toInt(event->u.enterLeave.rootX);
			ev->y_root	= cvtINT16toInt(event->u.enterLeave.rootY);
			ev->state	= event->u.enterLeave.state;
			ev->mode	= event->u.enterLeave.mode;
			ev->same_screen = (event->u.enterLeave.flags &
				ELFlagSameScreen) && True;
			ev->focus	= (event->u.enterLeave.flags &
			  	ELFlagFocus) && True;
			ev->detail	= event->u.u.detail;
		}
		  break;
	      case FocusIn:
	      case FocusOut:
		{
			register XFocusChangeEvent *ev = (XFocusChangeEvent *) re;
			ev->window 	= event->u.focus.window;
			ev->mode	= event->u.focus.mode;
			ev->detail	= event->u.u.detail;
		}
		  break;
	      case KeymapNotify:
		{
			register XKeymapEvent *ev = (XKeymapEvent *) re;
			ev->window	= None;
			memcpy(&ev->key_vector[1],
			       (char *)((xKeymapEvent *) event)->map,
			       sizeof (((xKeymapEvent *) event)->map));
		}
		break;
	      case Expose:
		{
			register XExposeEvent *ev = (XExposeEvent *) re;
			ev->window	= event->u.expose.window;
			ev->x		= event->u.expose.x;
			ev->y		= event->u.expose.y;
			ev->width	= event->u.expose.width;
			ev->height	= event->u.expose.height;
			ev->count	= event->u.expose.count;
		}
		break;
	      case GraphicsExpose:
		{
		    register XGraphicsExposeEvent *ev =
			(XGraphicsExposeEvent *) re;
		    ev->drawable	= event->u.graphicsExposure.drawable;
		    ev->x		= event->u.graphicsExposure.x;
		    ev->y		= event->u.graphicsExposure.y;
		    ev->width		= event->u.graphicsExposure.width;
		    ev->height		= event->u.graphicsExposure.height;
		    ev->count		= event->u.graphicsExposure.count;
		    ev->major_code	= event->u.graphicsExposure.majorEvent;
		    ev->minor_code	= event->u.graphicsExposure.minorEvent;
		}
		break;
	      case NoExpose:
		{
		    register XNoExposeEvent *ev = (XNoExposeEvent *) re;
		    ev->drawable	= event->u.noExposure.drawable;
		    ev->major_code	= event->u.noExposure.majorEvent;
		    ev->minor_code	= event->u.noExposure.minorEvent;
		}
		break;
	      case VisibilityNotify:
		{
		    register XVisibilityEvent *ev = (XVisibilityEvent *) re;
		    ev->window		= event->u.visibility.window;
		    ev->state		= event->u.visibility.state;
		}
		break;
	      case CreateNotify:
		{
		    register XCreateWindowEvent *ev =
			 (XCreateWindowEvent *) re;
		    ev->window		= event->u.createNotify.window;
		    ev->parent		= event->u.createNotify.parent;
		    ev->x		= cvtINT16toInt(event->u.createNotify.x);
		    ev->y		= cvtINT16toInt(event->u.createNotify.y);
		    ev->width		= event->u.createNotify.width;
		    ev->height		= event->u.createNotify.height;
		    ev->border_width	= event->u.createNotify.borderWidth;
		    ev->override_redirect	= event->u.createNotify.override;
		}
		break;
	      case DestroyNotify:
		{
		    register XDestroyWindowEvent *ev =
				(XDestroyWindowEvent *) re;
		    ev->window		= event->u.destroyNotify.window;
		    ev->event		= event->u.destroyNotify.event;
		}
		break;
	      case UnmapNotify:
		{
		    register XUnmapEvent *ev = (XUnmapEvent *) re;
		    ev->window		= event->u.unmapNotify.window;
		    ev->event		= event->u.unmapNotify.event;
		    ev->from_configure	= event->u.unmapNotify.fromConfigure;
		}
		break;
	      case MapNotify:
		{
		    register XMapEvent *ev = (XMapEvent *) re;
		    ev->window		= event->u.mapNotify.window;
		    ev->event		= event->u.mapNotify.event;
		    ev->override_redirect	= event->u.mapNotify.override;
		}
		break;
	      case MapRequest:
		{
		    register XMapRequestEvent *ev = (XMapRequestEvent *) re;
		    ev->window		= event->u.mapRequest.window;
		    ev->parent		= event->u.mapRequest.parent;
		}
		break;
	      case ReparentNotify:
		{
		    register XReparentEvent *ev = (XReparentEvent *) re;
		    ev->event		= event->u.reparent.event;
		    ev->window		= event->u.reparent.window;
		    ev->parent		= event->u.reparent.parent;
		    ev->x		= cvtINT16toInt(event->u.reparent.x);
		    ev->y		= cvtINT16toInt(event->u.reparent.y);
		    ev->override_redirect	= event->u.reparent.override;
		}
		break;
	      case ConfigureNotify:
		{
		    register XConfigureEvent *ev = (XConfigureEvent *) re;
		    ev->event	= event->u.configureNotify.event;
		    ev->window	= event->u.configureNotify.window;
		    ev->above	= event->u.configureNotify.aboveSibling;
		    ev->x	= cvtINT16toInt(event->u.configureNotify.x);
		    ev->y	= cvtINT16toInt(event->u.configureNotify.y);
		    ev->width	= event->u.configureNotify.width;
		    ev->height	= event->u.configureNotify.height;
		    ev->border_width  = event->u.configureNotify.borderWidth;
		    ev->override_redirect = event->u.configureNotify.override;
		}
		break;
	      case ConfigureRequest:
		{
		    register XConfigureRequestEvent *ev =
		        (XConfigureRequestEvent *) re;
		    ev->window		= event->u.configureRequest.window;
		    ev->parent		= event->u.configureRequest.parent;
		    ev->above		= event->u.configureRequest.sibling;
		    ev->x		= cvtINT16toInt(event->u.configureRequest.x);
		    ev->y		= cvtINT16toInt(event->u.configureRequest.y);
		    ev->width		= event->u.configureRequest.width;
		    ev->height		= event->u.configureRequest.height;
		    ev->border_width	= event->u.configureRequest.borderWidth;
		    ev->value_mask	= event->u.configureRequest.valueMask;
		    ev->detail  	= event->u.u.detail;
		}
		break;
	      case GravityNotify:
		{
		    register XGravityEvent *ev = (XGravityEvent *) re;
		    ev->window		= event->u.gravity.window;
		    ev->event		= event->u.gravity.event;
		    ev->x		= cvtINT16toInt(event->u.gravity.x);
		    ev->y		= cvtINT16toInt(event->u.gravity.y);
		}
		break;
	      case ResizeRequest:
		{
		    register XResizeRequestEvent *ev =
			(XResizeRequestEvent *) re;
		    ev->window		= event->u.resizeRequest.window;
		    ev->width		= event->u.resizeRequest.width;
		    ev->height		= event->u.resizeRequest.height;
		}
		break;
	      case CirculateNotify:
		{
		    register XCirculateEvent *ev = (XCirculateEvent *) re;
		    ev->window		= event->u.circulate.window;
		    ev->event		= event->u.circulate.event;
		    ev->place		= event->u.circulate.place;
		}
		break;
	      case CirculateRequest:
		{
		    register XCirculateRequestEvent *ev =
		        (XCirculateRequestEvent *) re;
		    ev->window		= event->u.circulate.window;
		    ev->parent		= event->u.circulate.event;
		    ev->place		= event->u.circulate.place;
		}
		break;
	      case PropertyNotify:
		{
		    register XPropertyEvent *ev = (XPropertyEvent *) re;
		    ev->window		= event->u.property.window;
		    ev->atom		= event->u.property.atom;
		    ev->time		= event->u.property.time;
		    ev->state		= event->u.property.state;
		}
		break;
	      case SelectionClear:
		{
		    register XSelectionClearEvent *ev =
			 (XSelectionClearEvent *) re;
		    ev->window		= event->u.selectionClear.window;
		    ev->selection	= event->u.selectionClear.atom;
		    ev->time		= event->u.selectionClear.time;
		}
		break;
	      case SelectionRequest:
		{
		    register XSelectionRequestEvent *ev =
		        (XSelectionRequestEvent *) re;
		    ev->owner		= event->u.selectionRequest.owner;
		    ev->requestor	= event->u.selectionRequest.requestor;
		    ev->selection	= event->u.selectionRequest.selection;
		    ev->target		= event->u.selectionRequest.target;
		    ev->property	= event->u.selectionRequest.property;
		    ev->time		= event->u.selectionRequest.time;
		}
		break;
	      case SelectionNotify:
		{
		    register XSelectionEvent *ev = (XSelectionEvent *) re;
		    ev->requestor	= event->u.selectionNotify.requestor;
		    ev->selection	= event->u.selectionNotify.selection;
		    ev->target		= event->u.selectionNotify.target;
		    ev->property	= event->u.selectionNotify.property;
		    ev->time		= event->u.selectionNotify.time;
		}
		break;
	      case ColormapNotify:
		{
		    register XColormapEvent *ev = (XColormapEvent *) re;
		    ev->window		= event->u.colormap.window;
		    ev->colormap	= event->u.colormap.colormap;
		    ev->new		= event->u.colormap.new;
		    ev->state		= event->u.colormap.state;
	        }
		break;
	      case ClientMessage:
		{
		   register int i;
		   register XClientMessageEvent *ev
		   			= (XClientMessageEvent *) re;
		   ev->window		= event->u.clientMessage.window;
		   ev->format		= event->u.u.detail;
		   switch (ev->format) {
			case 8:
			   ev->message_type = event->u.clientMessage.u.b.type;
			   for (i = 0; i < 20; i++)
			     ev->data.b[i] = event->u.clientMessage.u.b.bytes[i];
			   break;
			case 16:
			   ev->message_type = event->u.clientMessage.u.s.type;
			   ev->data.s[0] = cvtINT16toShort(event->u.clientMessage.u.s.shorts0);
			   ev->data.s[1] = cvtINT16toShort(event->u.clientMessage.u.s.shorts1);
			   ev->data.s[2] = cvtINT16toShort(event->u.clientMessage.u.s.shorts2);
			   ev->data.s[3] = cvtINT16toShort(event->u.clientMessage.u.s.shorts3);
			   ev->data.s[4] = cvtINT16toShort(event->u.clientMessage.u.s.shorts4);
			   ev->data.s[5] = cvtINT16toShort(event->u.clientMessage.u.s.shorts5);
			   ev->data.s[6] = cvtINT16toShort(event->u.clientMessage.u.s.shorts6);
			   ev->data.s[7] = cvtINT16toShort(event->u.clientMessage.u.s.shorts7);
			   ev->data.s[8] = cvtINT16toShort(event->u.clientMessage.u.s.shorts8);
			   ev->data.s[9] = cvtINT16toShort(event->u.clientMessage.u.s.shorts9);
			   break;
			case 32:
			   ev->message_type = event->u.clientMessage.u.l.type;
			   ev->data.l[0] = cvtINT32toLong(event->u.clientMessage.u.l.longs0);
			   ev->data.l[1] = cvtINT32toLong(event->u.clientMessage.u.l.longs1);
			   ev->data.l[2] = cvtINT32toLong(event->u.clientMessage.u.l.longs2);
			   ev->data.l[3] = cvtINT32toLong(event->u.clientMessage.u.l.longs3);
			   ev->data.l[4] = cvtINT32toLong(event->u.clientMessage.u.l.longs4);
			   break;
			default: /* XXX should never occur */
				break;
		    }
	        }
		break;
	      case MappingNotify:
		{
		   register XMappingEvent *ev = (XMappingEvent *)re;
		   ev->window		= 0;
		   ev->first_keycode 	= event->u.mappingNotify.firstKeyCode;
		   ev->request 		= event->u.mappingNotify.request;
		   ev->count 		= event->u.mappingNotify.count;
		}
		break;
	      default:
		return(_XUnknownWireEvent(dpy, re, event));
	}
	return(True);
}


/*
 * _XDefaultIOError - Default fatal system error reporting routine.  Called
 * when an X internal system error is encountered.
 */
int _XDefaultIOError(
	Display *dpy)
{
	if (ECHECK(EPIPE)) {
	    (void) fprintf (stderr,
	"X connection to %s broken (explicit kill or server shutdown).\r\n",
			    DisplayString (dpy));
	} else {
	    (void) fprintf (stderr,
			"XIO:  fatal IO error %d (%s) on X server \"%s\"\r\n",
#ifdef WIN32
			WSAGetLastError(), strerror(WSAGetLastError()),
#else
			errno, strerror (errno),
#endif
			DisplayString (dpy));
	    (void) fprintf (stderr,
	 "      after %lu requests (%lu known processed) with %d events remaining.\r\n",
			NextRequest(dpy) - 1, LastKnownRequestProcessed(dpy),
			QLength(dpy));

	}
#ifdef NX_TRANS_SOCKET
        if (_NXHandleDisplayError == 1)
        {
#ifdef NX_TRANS_TEST
            fprintf(stderr, "_XDefaultIOError: Going to return from the error handler.\n");
#endif
            return 0;
        }
        else
        {
#ifdef NX_TRANS_TEST
            fprintf(stderr, "_XDefaultIOError: Going to exit from the program.\n");
#endif
#ifdef NX_TRANS_EXIT
            NXTransExit(1);
#else
            exit(1);
#endif
        }
#else
        exit(1);
#endif /* #ifdef NX_TRANS_SOCKET */
        /*NOTREACHED*/
}


static int _XPrintDefaultError(
    Display *dpy,
    XErrorEvent *event,
    FILE *fp)
{
    char buffer[BUFSIZ];
    char mesg[BUFSIZ];
    char number[32];
    const char *mtype = "XlibMessage";
    register _XExtension *ext = (_XExtension *)NULL;
    _XExtension *bext = (_XExtension *)NULL;
    XGetErrorText(dpy, event->error_code, buffer, BUFSIZ);
    XGetErrorDatabaseText(dpy, mtype, "XError", "X Error", mesg, BUFSIZ);
    (void) fprintf(fp, "%s:  %s\n  ", mesg, buffer);
    XGetErrorDatabaseText(dpy, mtype, "MajorCode", "Request Major code %d",
	mesg, BUFSIZ);
    (void) fprintf(fp, mesg, event->request_code);
    if (event->request_code < 128) {
	snprintf(number, sizeof(number), "%d", event->request_code);
	XGetErrorDatabaseText(dpy, "XRequest", number, "", buffer, BUFSIZ);
    } else {
	for (ext = dpy->ext_procs;
	     ext && (ext->codes.major_opcode != event->request_code);
	     ext = ext->next)
	  ;
	if (ext) {
	    strncpy(buffer, ext->name, BUFSIZ);
	    buffer[BUFSIZ - 1] = '\0';
        } else
	    buffer[0] = '\0';
    }
    (void) fprintf(fp, " (%s)\n", buffer);
    if (event->request_code >= 128) {
	XGetErrorDatabaseText(dpy, mtype, "MinorCode", "Request Minor code %d",
			      mesg, BUFSIZ);
	fputs("  ", fp);
	(void) fprintf(fp, mesg, event->minor_code);
	if (ext) {
	    snprintf(mesg, sizeof(mesg), "%s.%d", ext->name, event->minor_code);
	    XGetErrorDatabaseText(dpy, "XRequest", mesg, "", buffer, BUFSIZ);
	    (void) fprintf(fp, " (%s)", buffer);
	}
	fputs("\n", fp);
    }
    if (event->error_code >= 128) {
	/* kludge, try to find the extension that caused it */
	buffer[0] = '\0';
	for (ext = dpy->ext_procs; ext; ext = ext->next) {
	    if (ext->error_string)
		(*ext->error_string)(dpy, event->error_code, &ext->codes,
				     buffer, BUFSIZ);
	    if (buffer[0]) {
		bext = ext;
		break;
	    }
	    if (ext->codes.first_error &&
		ext->codes.first_error < (int)event->error_code &&
		(!bext || ext->codes.first_error > bext->codes.first_error))
		bext = ext;
	}
	if (bext)
	    snprintf(buffer, sizeof(buffer), "%s.%d", bext->name,
                     event->error_code - bext->codes.first_error);
	else
	    strcpy(buffer, "Value");
	XGetErrorDatabaseText(dpy, mtype, buffer, "", mesg, BUFSIZ);
	if (mesg[0]) {
	    fputs("  ", fp);
	    (void) fprintf(fp, mesg, event->resourceid);
	    fputs("\n", fp);
	}
	/* let extensions try to print the values */
	for (ext = dpy->ext_procs; ext; ext = ext->next) {
	    if (ext->error_values)
		(*ext->error_values)(dpy, event, fp);
	}
    } else if ((event->error_code == BadWindow) ||
	       (event->error_code == BadPixmap) ||
	       (event->error_code == BadCursor) ||
	       (event->error_code == BadFont) ||
	       (event->error_code == BadDrawable) ||
	       (event->error_code == BadColor) ||
	       (event->error_code == BadGC) ||
	       (event->error_code == BadIDChoice) ||
	       (event->error_code == BadValue) ||
	       (event->error_code == BadAtom)) {
	if (event->error_code == BadValue)
	    XGetErrorDatabaseText(dpy, mtype, "Value", "Value 0x%x",
				  mesg, BUFSIZ);
	else if (event->error_code == BadAtom)
	    XGetErrorDatabaseText(dpy, mtype, "AtomID", "AtomID 0x%x",
				  mesg, BUFSIZ);
	else
	    XGetErrorDatabaseText(dpy, mtype, "ResourceID", "ResourceID 0x%x",
				  mesg, BUFSIZ);
	fputs("  ", fp);
	(void) fprintf(fp, mesg, event->resourceid);
	fputs("\n", fp);
    }
    XGetErrorDatabaseText(dpy, mtype, "ErrorSerial", "Error Serial #%d",
			  mesg, BUFSIZ);
    fputs("  ", fp);
    (void) fprintf(fp, mesg, event->serial);
    XGetErrorDatabaseText(dpy, mtype, "CurrentSerial", "Current Serial #%lld",
			  mesg, BUFSIZ);
    fputs("\n  ", fp);
    (void) fprintf(fp, mesg, (unsigned long long)(X_DPY_GET_REQUEST(dpy)));
    fputs("\n", fp);
    if (event->error_code == BadImplementation) return 0;
    return 1;
}

int _XDefaultError(
	Display *dpy,
	XErrorEvent *event)
{
    if (_XPrintDefaultError (dpy, event, stderr) == 0) return 0;

    /*
     * Store in dpy flags that the client is exiting on an unhandled XError
     * (pretend it is an IOError, since the application is dying anyway it
     * does not make a difference).
     * This is useful for _XReply not to hang if the application makes Xlib
     * calls in _fini as part of process termination.
     */
    dpy->flags |= XlibDisplayIOError;

    exit(1);
    /*NOTREACHED*/
}

/*ARGSUSED*/
Bool _XDefaultWireError(Display *display, XErrorEvent *he, xError *we)
{
    return True;
}

/*
 * _XError - upcall internal or user protocol error handler
 */
int _XError (
    Display *dpy,
    register xError *rep)
{
    /*
     * X_Error packet encountered!  We need to unpack the error before
     * giving it to the user.
     */
    XEvent event; /* make it a large event */
    register _XAsyncHandler *async, *next;

    event.xerror.serial = _XSetLastRequestRead(dpy, (xGenericReply *)rep);

    for (async = dpy->async_handlers; async; async = next) {
	next = async->next;
	if ((*async->handler)(dpy, (xReply *)rep,
			      (char *)rep, SIZEOF(xError), async->data))
	    return 0;
    }

    event.xerror.display = dpy;
    event.xerror.type = X_Error;
    event.xerror.resourceid = rep->resourceID;
    event.xerror.error_code = rep->errorCode;
    event.xerror.request_code = rep->majorCode;
    event.xerror.minor_code = rep->minorCode;
    if (dpy->error_vec &&
	!(*dpy->error_vec[rep->errorCode])(dpy, &event.xerror, rep))
	return 0;
    if (_XErrorFunction != NULL) {
	int rtn_val;
#ifdef XTHREADS
	if (dpy->lock)
	    (*dpy->lock->user_lock_display)(dpy);
	UnlockDisplay(dpy);
#endif
	rtn_val = (*_XErrorFunction)(dpy, (XErrorEvent *)&event); /* upcall */
#ifdef XTHREADS
	LockDisplay(dpy);
	if (dpy->lock)
	    (*dpy->lock->user_unlock_display)(dpy);
#endif
	return rtn_val;
    } else {
	return _XDefaultError(dpy, (XErrorEvent *)&event);
    }
}

/*
 * _XIOError - call user connection error handler and exit
 */
int
_XIOError (
    Display *dpy)
{
    dpy->flags |= XlibDisplayIOError;
#ifdef WIN32
    errno = WSAGetLastError();
#endif

    /* This assumes that the thread calling exit will call any atexit handlers.
     * If this does not hold, then an alternate solution would involve
     * registering an atexit handler to take over the lock, which would only
     * assume that the same thread calls all the atexit handlers. */
#ifdef XTHREADS
    if (dpy->lock)
	(*dpy->lock->user_lock_display)(dpy);
#endif
    UnlockDisplay(dpy);

    if (_XIOErrorFunction != NULL)
	(*_XIOErrorFunction)(dpy);
    else
	_XDefaultIOError(dpy);
#ifdef NX_TRANS_SOCKET
    /*
     * Check if we are supposed to return in the case
     * of a display failure. The client which originated
     * the X operation will have to check the value of
     * the XlibDisplayIOError flag and handle appropria-
     * tely the display disconnection.
     */

    if (_NXHandleDisplayError == 0)
    {
#ifdef NX_TRANS_EXIT
        NXTransExit(1);
#else
        exit(1);
#endif
    }

    /*
     * We are going to return. Reset the display
     * buffers. Further writes will be discarded.
     */

#ifdef NX_TRANS_TEST
    fprintf(stderr, "_XIOError: Resetting the display buffer.\n");
#endif

    dpy->bufptr = dpy->buffer;
    dpy->last_req = (char *) &_dummy_request;

#ifdef NX_TRANS_TEST
    fprintf(stderr, "_XIOError: Resetting the display flags.\n");
#endif

    dpy->flags &= ~XlibDisplayProcConni;
    dpy->flags &= ~XlibDisplayPrivSync;
    dpy->flags &= ~XlibDisplayReadEvents;
    dpy->flags &= ~XlibDisplayWriting;
    dpy->flags &= ~XlibDisplayReply;
    /* shut up the compiler by returning something */
    return 0;
#else
    exit (1);
#endif
    /*NOTREACHED*/
}


/*
 * This routine can be used to (cheaply) get some memory within a single
 * Xlib routine for scratch space.  A single buffer is reused each time
 * if possible.  To be MT safe, you can only call this between a call to
 * GetReq* and a call to Data* or _XSend*, or in a context when the thread
 * is guaranteed to not unlock the display.
 */
char *_XAllocScratch(
	register Display *dpy,
	unsigned long nbytes)
{
	if (nbytes > dpy->scratch_length) {
	    Xfree (dpy->scratch_buffer);
	    dpy->scratch_buffer = Xmalloc(nbytes);
	    if (dpy->scratch_buffer)
		dpy->scratch_length = nbytes;
	    else dpy->scratch_length = 0;
	}
	return (dpy->scratch_buffer);
}

/*
 * Scratch space allocator you can call any time, multiple times, and be
 * MT safe, but you must hand the buffer back with _XFreeTemp.
 */
char *_XAllocTemp(
    register Display *dpy,
    unsigned long nbytes)
{
    char *buf;

    buf = _XAllocScratch(dpy, nbytes);
    dpy->scratch_buffer = NULL;
    dpy->scratch_length = 0;
    return buf;
}

void _XFreeTemp(
    register Display *dpy,
    char *buf,
    unsigned long nbytes)
{

    Xfree(dpy->scratch_buffer);
    dpy->scratch_buffer = buf;
    dpy->scratch_length = nbytes;
}

/*
 * Given a visual id, find the visual structure for this id on this display.
 */
Visual *_XVIDtoVisual(
	Display *dpy,
	VisualID id)
{
	register int i, j, k;
	register Screen *sp;
	register Depth *dp;
	register Visual *vp;
	for (i = 0; i < dpy->nscreens; i++) {
		sp = &dpy->screens[i];
		for (j = 0; j < sp->ndepths; j++) {
			dp = &sp->depths[j];
			/* if nvisuals == 0 then visuals will be NULL */
			for (k = 0; k < dp->nvisuals; k++) {
				vp = &dp->visuals[k];
				if (vp->visualid == id) return (vp);
			}
		}
	}
	return (NULL);
}

int
XFree (void *data)
{
	Xfree (data);
	return 1;
}

#ifdef _XNEEDBCOPYFUNC
void _Xbcopy(b1, b2, length)
    register char *b1, *b2;
    register length;
{
    if (b1 < b2) {
	b2 += length;
	b1 += length;
	while (length--)
	    *--b2 = *--b1;
    } else {
	while (length--)
	    *b2++ = *b1++;
    }
}
#endif

#ifdef DataRoutineIsProcedure
void Data(
	Display *dpy,
	_Xconst char *data,
	long len)
{
	if (dpy->bufptr + (len) <= dpy->bufmax) {
		memcpy(dpy->bufptr, data, (int)len);
		dpy->bufptr += ((len) + 3) & ~3;
	} else {
		_XSend(dpy, data, len);
	}
}
#endif /* DataRoutineIsProcedure */


#ifdef LONG64
int
_XData32(
    Display *dpy,
    register _Xconst long *data,
    unsigned len)
{
    register int *buf;
    register long i;

    while (len) {
	buf = (int *)dpy->bufptr;
	i = dpy->bufmax - (char *)buf;
	if (!i) {
	    _XFlush(dpy);
	    continue;
	}
	if (len < i)
	    i = len;
	dpy->bufptr = (char *)buf + i;
	len -= i;
	i >>= 2;
	while (--i >= 0)
	    *buf++ = *data++;
    }
    return 0;
}
#endif /* LONG64 */



/* Make sure this produces the same string as DefineLocal/DefineSelf in xdm.
 * Otherwise, Xau will not be able to find your cookies in the Xauthority file.
 *
 * Note: POSIX says that the ``nodename'' member of utsname does _not_ have
 *       to have sufficient information for interfacing to the network,
 *       and so, you may be better off using gethostname (if it exists).
 */

#if defined(_POSIX_SOURCE) || defined(SVR4)
#define NEED_UTSNAME
#include <sys/utsname.h>
#else
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#endif

/*
 * _XGetHostname - similar to gethostname but allows special processing.
 */
int _XGetHostname (
    char *buf,
    int maxlen)
{
    int len;

#ifdef NEED_UTSNAME
    struct utsname name;

    if (maxlen <= 0 || buf == NULL)
	return 0;

    uname (&name);
    len = strlen (name.nodename);
    if (len >= maxlen) len = maxlen - 1;
    strncpy (buf, name.nodename, len);
    buf[len] = '\0';
#else
    if (maxlen <= 0 || buf == NULL)
	return 0;

    buf[0] = '\0';
    (void) gethostname (buf, maxlen);
    buf [maxlen - 1] = '\0';
    len = strlen(buf);
#endif /* NEED_UTSNAME */
    return len;
}


/*
 * _XScreenOfWindow - get the Screen of a given window
 */

Screen *_XScreenOfWindow(Display *dpy, Window w)
{
    register int i;
    Window root;
    int x, y;				/* dummy variables */
    unsigned int width, height, bw, depth;  /* dummy variables */

    if (XGetGeometry (dpy, w, &root, &x, &y, &width, &height,
		      &bw, &depth) == False) {
	return NULL;
    }
    for (i = 0; i < ScreenCount (dpy); i++) {	/* find root from list */
	if (root == RootWindow (dpy, i)) {
	    return ScreenOfDisplay (dpy, i);
	}
    }
    return NULL;
}

/*
 * WARNING: This implementation's pre-conditions and post-conditions
 * must remain compatible with the old macro-based implementations of
 * GetReq, GetReqExtra, GetResReq, and GetEmptyReq. The portions of the
 * Display structure affected by those macros are part of libX11's
 * ABI.
 */
void *_XGetRequest(Display *dpy, CARD8 type, size_t len)
{
    xReq *req;

    if (dpy->bufptr + len > dpy->bufmax)
	_XFlush(dpy);
    /* Request still too large, so do not allow it to overflow. */
    if (dpy->bufptr + len > dpy->bufmax) {
	fprintf(stderr,
		"Xlib: request %d length %zd would exceed buffer size.\n",
		type, len);
	/* Changes failure condition from overflow to NULL dereference. */
	return NULL;
    }

    if (len % 4)
	fprintf(stderr,
		"Xlib: request %d length %zd not a multiple of 4.\n",
		type, len);

    dpy->last_req = dpy->bufptr;

    req = (xReq*)dpy->bufptr;
    req->reqType = type;
    req->length = len / 4;
    dpy->bufptr += len;
    X_DPY_REQUEST_INCREMENT(dpy);
    return req;
}

#if defined(WIN32)

/*
 * These functions are intended to be used internally to Xlib only.
 * These functions will always prefix the path with a DOS drive in the
 * form "<drive-letter>:". As such, these functions are only suitable
 * for use by Xlib function that supply a root-based path to some
 * particular file, e.g. <ProjectRoot>/lib/X11/locale/locale.dir will
 * be converted to "C:/usr/X11R6.3/lib/X11/locale/locale.dir".
 */

static int access_file (path, pathbuf, len_pathbuf, pathret)
    char* path;
    char* pathbuf;
    int len_pathbuf;
    char** pathret;
{
    if (access (path, F_OK) == 0) {
	if (strlen (path) < len_pathbuf)
	    *pathret = pathbuf;
	else
	    *pathret = Xmalloc (strlen (path) + 1);
	if (*pathret) {
	    strcpy (*pathret, path);
	    return 1;
	}
    }
    return 0;
}

static int AccessFile (path, pathbuf, len_pathbuf, pathret)
    char* path;
    char* pathbuf;
    int len_pathbuf;
    char** pathret;
{
    unsigned long drives;
    int i, len;
    char* drive;
    char buf[MAX_PATH];
    char* bufp;

    /* just try the "raw" name first and see if it works */
    if (access_file (path, pathbuf, len_pathbuf, pathret))
	return 1;

    /* try the places set in the environment */
    drive = getenv ("_XBASEDRIVE");
    if (!drive)
	drive = "C:";
    len = strlen (drive) + strlen (path);
    if (len < MAX_PATH) bufp = buf;
    else bufp = Xmalloc (len + 1);
    strcpy (bufp, drive);
    strcat (bufp, path);
    if (access_file (bufp, pathbuf, len_pathbuf, pathret)) {
	if (bufp != buf) Xfree (bufp);
	return 1;
    }

    /* one last place to look */
    drive = getenv ("HOMEDRIVE");
    if (drive) {
	len = strlen (drive) + strlen (path);
	if (len < MAX_PATH) bufp = buf;
	else bufp = Xmalloc (len + 1);
	strcpy (bufp, drive);
	strcat (bufp, path);
	if (access_file (bufp, pathbuf, len_pathbuf, pathret)) {
	    if (bufp != buf) Xfree (bufp);
	    return 1;
	}
    }

    /* tried everywhere else, go fishing */
#define C_DRIVE ('C' - 'A')
#define Z_DRIVE ('Z' - 'A')
    /* does OS/2 (with or with gcc-emx) have getdrives? */
    drives = _getdrives ();
    for (i = C_DRIVE; i <= Z_DRIVE; i++) { /* don't check on A: or B: */
	if ((1 << i) & drives) {
	    len = 2 + strlen (path);
	    if (len < MAX_PATH) bufp = buf;
	    else bufp = Xmalloc (len + 1);
	    *bufp = 'A' + i;
	    *(bufp + 1) = ':';
	    *(bufp + 2) = '\0';
	    strcat (bufp, path);
	    if (access_file (bufp, pathbuf, len_pathbuf, pathret)) {
		if (bufp != buf) Xfree (bufp);
		return 1;
	    }
	}
    }
    return 0;
}

int _XOpenFile(path, flags)
    _Xconst char* path;
    int flags;
{
    char buf[MAX_PATH];
    char* bufp = NULL;
    int ret = -1;
    UINT olderror = SetErrorMode (SEM_FAILCRITICALERRORS);

    if (AccessFile (path, buf, MAX_PATH, &bufp))
	ret = open (bufp, flags);

    (void) SetErrorMode (olderror);

    if (bufp != buf) Xfree (bufp);

    return ret;
}

int _XOpenFileMode(path, flags, mode)
    _Xconst char* path;
    int flags;
    mode_t mode;
{
    char buf[MAX_PATH];
    char* bufp = NULL;
    int ret = -1;
    UINT olderror = SetErrorMode (SEM_FAILCRITICALERRORS);

    if (AccessFile (path, buf, MAX_PATH, &bufp))
	ret = open (bufp, flags, mode);

    (void) SetErrorMode (olderror);

    if (bufp != buf) Xfree (bufp);

    return ret;
}

void* _XFopenFile(path, mode)
    _Xconst char* path;
    _Xconst char* mode;
{
    char buf[MAX_PATH];
    char* bufp = NULL;
    void* ret = NULL;
    UINT olderror = SetErrorMode (SEM_FAILCRITICALERRORS);

    if (AccessFile (path, buf, MAX_PATH, &bufp))
	ret = fopen (bufp, mode);

    (void) SetErrorMode (olderror);

    if (bufp != buf) Xfree (bufp);

    return ret;
}

int _XAccessFile(path)
    _Xconst char* path;
{
    char buf[MAX_PATH];
    char* bufp;
    int ret = -1;
    UINT olderror = SetErrorMode (SEM_FAILCRITICALERRORS);

    ret = AccessFile (path, buf, MAX_PATH, &bufp);

    (void) SetErrorMode (olderror);

    if (bufp != buf) Xfree (bufp);

    return ret;
}

#endif

#ifdef WIN32
#undef _Xdebug
int _Xdebug = 0;
int *_Xdebug_p = &_Xdebug;
void (**_XCreateMutex_fn_p)(LockInfoPtr) = &_XCreateMutex_fn;
void (**_XFreeMutex_fn_p)(LockInfoPtr) = &_XFreeMutex_fn;
void (**_XLockMutex_fn_p)(LockInfoPtr
#if defined(XTHREADS_WARN) || defined(XTHREADS_FILE_LINE)
    , char * /* file */
    , int /* line */
#endif
        ) = &_XLockMutex_fn;
void (**_XUnlockMutex_fn_p)(LockInfoPtr
#if defined(XTHREADS_WARN) || defined(XTHREADS_FILE_LINE)
    , char * /* file */
    , int /* line */
#endif
        ) = &_XUnlockMutex_fn;
LockInfoPtr *_Xglobal_lock_p = &_Xglobal_lock;
#endif