Plan 9 from Bell Labs’s /usr/web/sources/contrib/fgb/root/sys/src/ape/X11/cmd/X/xkb/XKBMAlloc.c

Copyright © 2021 Plan 9 Foundation.
Distributed under the MIT License.
Download the Plan 9 distribution.


/************************************************************
Copyright (c) 1993 by Silicon Graphics Computer Systems, Inc.

Permission to use, copy, modify, and distribute this
software and its documentation for any purpose and without
fee is hereby granted, provided that the above copyright
notice appear in all copies and that both that copyright
notice and this permission notice appear in supporting
documentation, and that the name of Silicon Graphics not be 
used in advertising or publicity pertaining to distribution 
of the software without specific prior written permission.
Silicon Graphics makes no representation about the suitability 
of this software for any purpose. It is provided "as is"
without any express or implied warranty.

SILICON GRAPHICS DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS 
SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY 
AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL SILICON
GRAPHICS BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL 
DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, 
DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE 
OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION  WITH
THE USE OR PERFORMANCE OF THIS SOFTWARE.

********************************************************/

#ifdef HAVE_DIX_CONFIG_H
#include <dix-config.h>
#elif defined(HAVE_CONFIG_H)
#include <config.h>
#endif

#include <stdio.h>
#include <X11/X.h>
#define	NEED_EVENTS
#define	NEED_REPLIES
#include <X11/Xproto.h>
#include "misc.h"
#include "inputstr.h"
#include <X11/keysym.h>
#define	XKBSRV_NEED_FILE_FUNCS
#include <xkbsrv.h>

/***====================================================================***/

Status
XkbAllocClientMap(XkbDescPtr xkb,unsigned which,unsigned nTotalTypes)
{
register int	i;
XkbClientMapPtr map;

    if ((xkb==NULL)||((nTotalTypes>0)&&(nTotalTypes<XkbNumRequiredTypes)))
	return BadValue;
    if ((which&XkbKeySymsMask)&&
	((!XkbIsLegalKeycode(xkb->min_key_code))||
	 (!XkbIsLegalKeycode(xkb->max_key_code))||
	 (xkb->max_key_code<xkb->min_key_code))) {
#ifdef DEBUG
fprintf(stderr,"bad keycode (%d,%d) in XkbAllocClientMap\n",
				xkb->min_key_code,xkb->max_key_code);
#endif
	return BadValue;
    }

    if (xkb->map==NULL) {
	map= _XkbTypedCalloc(1,XkbClientMapRec);
	if (map==NULL)
	    return BadAlloc;
	xkb->map= map;
    }
    else map= xkb->map;

    if ((which&XkbKeyTypesMask)&&(nTotalTypes>0)) {
	if (map->types==NULL) {
	    map->types= _XkbTypedCalloc(nTotalTypes,XkbKeyTypeRec);
	    if (map->types==NULL)
		return BadAlloc;
	    map->num_types= 0;
	    map->size_types= nTotalTypes;
	}
	else if (map->size_types<nTotalTypes) {
	    XkbKeyTypeRec *prev_types = map->types;

	    map->types= _XkbTypedRealloc(map->types,nTotalTypes,XkbKeyTypeRec);
	    if (map->types==NULL) {
		_XkbFree(prev_types);
		map->num_types= map->size_types= 0;
		return BadAlloc;
	    }
	    map->size_types= nTotalTypes;
	    bzero(&map->types[map->num_types], 
		  ((map->size_types-map->num_types)*sizeof(XkbKeyTypeRec)));
	}
    }
    if (which&XkbKeySymsMask) {
	int nKeys= XkbNumKeys(xkb);
	if (map->syms==NULL) {
	    map->size_syms= (nKeys*15)/10;
	    map->syms= _XkbTypedCalloc(map->size_syms,KeySym);
	    if (!map->syms) {
		map->size_syms= 0;
		return BadAlloc;
	    }
	    map->num_syms= 1;
	    map->syms[0]= NoSymbol;
	}
	if (map->key_sym_map==NULL) {
	    i= xkb->max_key_code+1;
	    map->key_sym_map= _XkbTypedCalloc(i,XkbSymMapRec);
	    if (map->key_sym_map==NULL)
		return BadAlloc;
	}
    }
    if (which&XkbModifierMapMask) {
	if ((!XkbIsLegalKeycode(xkb->min_key_code))||
	    (!XkbIsLegalKeycode(xkb->max_key_code))||
	    (xkb->max_key_code<xkb->min_key_code))
	    return BadMatch;
	if (map->modmap==NULL) {
	    i= xkb->max_key_code+1;
	    map->modmap= _XkbTypedCalloc(i,unsigned char);
	    if (map->modmap==NULL)
		return BadAlloc;
	}
    }
    return Success;
}

Status
XkbAllocServerMap(XkbDescPtr xkb,unsigned which,unsigned nNewActions)
{
register int	i;
XkbServerMapPtr map;

    if (xkb==NULL)
	return BadMatch;
    if (xkb->server==NULL) {
	map= _XkbTypedCalloc(1,XkbServerMapRec);
	if (map==NULL)
	    return BadAlloc;
	for (i=0;i<XkbNumVirtualMods;i++) {
	    map->vmods[i]= XkbNoModifierMask;
	}
	xkb->server= map;
    }
    else map= xkb->server;
    if (which&XkbExplicitComponentsMask) {
	if ((!XkbIsLegalKeycode(xkb->min_key_code))||
	    (!XkbIsLegalKeycode(xkb->max_key_code))||
	    (xkb->max_key_code<xkb->min_key_code))
	    return BadMatch;
	if (map->explicit==NULL) {
	    i= xkb->max_key_code+1;
	    map->explicit= _XkbTypedCalloc(i,unsigned char);
	    if (map->explicit==NULL)
		return BadAlloc;
	}
    }
    if (which&XkbKeyActionsMask) {
	if ((!XkbIsLegalKeycode(xkb->min_key_code))||
	    (!XkbIsLegalKeycode(xkb->max_key_code))||
	    (xkb->max_key_code<xkb->min_key_code))
	    return BadMatch;
        if (nNewActions<1)
	    nNewActions= 1;
	if (map->acts==NULL) {
	    map->acts= _XkbTypedCalloc((nNewActions+1),XkbAction);
	    if (map->acts==NULL)
		return BadAlloc;
	    map->num_acts= 1;
	    map->size_acts= nNewActions+1;
	}
	else if ((map->size_acts-map->num_acts)<nNewActions) {
	    unsigned need;
	    XkbAction *prev_acts = map->acts;
	    need= map->num_acts+nNewActions;
	    map->acts= _XkbTypedRealloc(map->acts,need,XkbAction);
	    if (map->acts==NULL) {
		_XkbFree(prev_acts);
	        map->num_acts= map->size_acts= 0;
	        return BadAlloc;
	    }
	    map->size_acts= need;
	    bzero(&map->acts[map->num_acts], 
		    ((map->size_acts-map->num_acts)*sizeof(XkbAction)));
	}
	if (map->key_acts==NULL) {
	    i= xkb->max_key_code+1;
	    map->key_acts= _XkbTypedCalloc(i,unsigned short);
	    if (map->key_acts==NULL)
		return BadAlloc;
	}
    }
    if (which&XkbKeyBehaviorsMask) {
	if ((!XkbIsLegalKeycode(xkb->min_key_code))||
	    (!XkbIsLegalKeycode(xkb->max_key_code))||
	    (xkb->max_key_code<xkb->min_key_code))
	    return BadMatch;
	if (map->behaviors==NULL) {
	    i= xkb->max_key_code+1;
	    map->behaviors= _XkbTypedCalloc(i,XkbBehavior);
	    if (map->behaviors==NULL)
		return BadAlloc;
	}
    }
    if (which&XkbVirtualModMapMask) {
	if ((!XkbIsLegalKeycode(xkb->min_key_code))||
	    (!XkbIsLegalKeycode(xkb->max_key_code))||
	    (xkb->max_key_code<xkb->min_key_code))
	    return BadMatch;
	if (map->vmodmap==NULL) {
	    i= xkb->max_key_code+1;
	    map->vmodmap= _XkbTypedCalloc(i,unsigned short);
	    if (map->vmodmap==NULL)
		return BadAlloc;
	}
    }
    return Success;
}

/***====================================================================***/

static Status
XkbCopyKeyType(XkbKeyTypePtr from,XkbKeyTypePtr into)
{
    if ((!from)||(!into))
	return BadMatch;
    if (into->map) {
	_XkbFree(into->map);
	into->map= NULL;
    }
    if (into->preserve) {
	_XkbFree(into->preserve);
	into->preserve= NULL;
    }
    if (into->level_names) {
	_XkbFree(into->level_names);
	into->level_names= NULL;
    }
    *into= *from;
    if ((from->map)&&(into->map_count>0)) {
	into->map= _XkbTypedCalloc(into->map_count,XkbKTMapEntryRec);
	if (!into->map)
	    return BadAlloc;
	memcpy(into->map,from->map,into->map_count*sizeof(XkbKTMapEntryRec));
    }
    if ((from->preserve)&&(into->map_count>0)) {
	into->preserve= _XkbTypedCalloc(into->map_count,XkbModsRec);
	if (!into->preserve)
	    return BadAlloc;
	memcpy(into->preserve,from->preserve,
				into->map_count*sizeof(XkbModsRec));
    }
    if ((from->level_names)&&(into->num_levels>0)) {
	into->level_names= _XkbTypedCalloc(into->num_levels,Atom);
	if (!into->level_names)
	    return BadAlloc;
	memcpy(into->level_names,from->level_names,
				 into->num_levels*sizeof(Atom));
    }
    return Success;
}

Status
XkbCopyKeyTypes(XkbKeyTypePtr from,XkbKeyTypePtr into,int num_types)
{
register int i,rtrn;

    if ((!from)||(!into)||(num_types<0))
	return BadMatch;
    for (i=0;i<num_types;i++) {
	if ((rtrn= XkbCopyKeyType(from++,into++))!=Success)
	    return rtrn;
    }
    return Success;
}

Status
XkbResizeKeyType(	XkbDescPtr	xkb,
			int		type_ndx,
			int		map_count,
			Bool		want_preserve,
			int		new_num_lvls)
{
XkbKeyTypePtr	type;
KeyCode		matchingKeys[XkbMaxKeyCount],nMatchingKeys;

    if ((type_ndx<0)||(type_ndx>=xkb->map->num_types)||(map_count<0)||
    							(new_num_lvls<1))
	return BadValue;
    switch (type_ndx) {
	case XkbOneLevelIndex:
	    if (new_num_lvls!=1)
		return BadMatch;
	    break;
	case XkbTwoLevelIndex:
	case XkbAlphabeticIndex:
	case XkbKeypadIndex:
	    if (new_num_lvls!=2)
		return BadMatch;
	    break;
    }
    type= &xkb->map->types[type_ndx];
    if (map_count==0) {
	if (type->map!=NULL)
	    _XkbFree(type->map);
	type->map= NULL;
	if (type->preserve!=NULL)
	    _XkbFree(type->preserve);
	type->preserve= NULL;
	type->map_count= 0;
    }
    else {
	XkbKTMapEntryRec *prev_map = type->map;

	if ((map_count>type->map_count)||(type->map==NULL))
	    type->map=_XkbTypedRealloc(type->map,map_count,XkbKTMapEntryRec);
	if (!type->map) {
	    if (prev_map) 
		_XkbFree(prev_map);
	    return BadAlloc;
	}
	if (want_preserve) {
	    XkbModsRec *prev_preserve = type->preserve;

	    if ((map_count>type->map_count)||(type->preserve==NULL)) {
		type->preserve= _XkbTypedRealloc(type->preserve,map_count,
	     						    XkbModsRec);
	    }
	    if (!type->preserve) {
		if (prev_preserve) 
		    _XkbFree(prev_preserve);
		return BadAlloc;
	    }
	}
	else if (type->preserve!=NULL) {
	    _XkbFree(type->preserve);
	    type->preserve= NULL;
	}
	type->map_count= map_count;
    }

    if ((new_num_lvls>type->num_levels)||(type->level_names==NULL)) {
	Atom * prev_level_names = type->level_names;

	type->level_names=_XkbTypedRealloc(type->level_names,new_num_lvls,Atom);
	if (!type->level_names) {
	    if (prev_level_names) 
		_XkbFree(prev_level_names);
	    return BadAlloc;
	}
    }
    /*
     * Here's the theory:
     *    If the width of the type changed, we might have to resize the symbol
     * maps for any keys that use the type for one or more groups.  This is
     * expensive, so we'll try to cull out any keys that are obviously okay:
     * In any case:
     *    - keys that have a group width <= the old width are okay (because
     *      they could not possibly have been associated with the old type)
     * If the key type increased in size:
     *    - keys that already have a group width >= to the new width are okay
     *    + keys that have a group width >= the old width but < the new width
     *      might have to be enlarged.
     * If the key type decreased in size:
     *    - keys that have a group width > the old width don't have to be
     *      resized (because they must have some other wider type associated 
     *      with some group).
     *    + keys that have a group width == the old width might have to be
     *      shrunk.
     * The possibilities marked with '+' require us to examine the key types
     * associated with each group for the key.
     */
    bzero(matchingKeys,XkbMaxKeyCount*sizeof(KeyCode));
    nMatchingKeys= 0;
    if (new_num_lvls>type->num_levels) {
	int	 		nTotal;
	KeySym	*		newSyms;
	int			width,match,nResize;
	register int		i,g,nSyms;

	nResize= 0;
	for (nTotal=1,i=xkb->min_key_code;i<=xkb->max_key_code;i++) {
	    width= XkbKeyGroupsWidth(xkb,i);
	    if (width<type->num_levels)
		continue;
	    for (match=0,g=XkbKeyNumGroups(xkb,i)-1;(g>=0)&&(!match);g--) {
		if (XkbKeyKeyTypeIndex(xkb,i,g)==type_ndx) {
		    matchingKeys[nMatchingKeys++]= i;
		    match= 1;
		}
	    }
	    if ((!match)||(width>=new_num_lvls))
		nTotal+= XkbKeyNumSyms(xkb,i);
	    else {
		nTotal+= XkbKeyNumGroups(xkb,i)*new_num_lvls;
		nResize++;
	    }
	}
	if (nResize>0) {
	    int nextMatch;
	    xkb->map->size_syms= (nTotal*15)/10;
	    newSyms = _XkbTypedCalloc(xkb->map->size_syms,KeySym);
	    if (newSyms==NULL)
		return BadAlloc;
	    nextMatch= 0;
	    nSyms= 1;
	    for (i=xkb->min_key_code;i<=xkb->max_key_code;i++) {
		if (matchingKeys[nextMatch]==i) {
		    KeySym *pOld;
		    nextMatch++;
		    width= XkbKeyGroupsWidth(xkb,i);
		    pOld= XkbKeySymsPtr(xkb,i);
		    for (g=XkbKeyNumGroups(xkb,i)-1;g>=0;g--) {
			memcpy(&newSyms[nSyms+(new_num_lvls*g)],&pOld[width*g],
							width*sizeof(KeySym));
		    }
		    xkb->map->key_sym_map[i].offset= nSyms;
		    nSyms+= XkbKeyNumGroups(xkb,i)*new_num_lvls;
		}
		else {
		    memcpy(&newSyms[nSyms],XkbKeySymsPtr(xkb,i),
					XkbKeyNumSyms(xkb,i)*sizeof(KeySym));
		    xkb->map->key_sym_map[i].offset= nSyms;
		    nSyms+= XkbKeyNumSyms(xkb,i);
		}
	    }
	    type->num_levels= new_num_lvls;
	    _XkbFree(xkb->map->syms);
	    xkb->map->syms= newSyms;
	    xkb->map->num_syms= nSyms;
	    return Success;
	}
    }
    else if (new_num_lvls<type->num_levels) {
	int 		width,match;
	register int	g,i;
	for (i=xkb->min_key_code;i<=xkb->max_key_code;i++) {
	    width= XkbKeyGroupsWidth(xkb,i);
	    if (width<type->num_levels)
		continue;
	    for (match=0,g=XkbKeyNumGroups(xkb,i)-1;(g>=0)&&(!match);g--) {
		if (XkbKeyKeyTypeIndex(xkb,i,g)==type_ndx) {
		    matchingKeys[nMatchingKeys++]= i;
		    match= 1;
		}
	    }
	}
    }
    if (nMatchingKeys>0) {
	int 		key,firstClear;
	register int	i,g;
	if (new_num_lvls>type->num_levels)
	     firstClear= type->num_levels;
	else firstClear= new_num_lvls;
	for (i=0;i<nMatchingKeys;i++) {
	    KeySym *	pSyms;
	    int		width,nClear;

	    key= matchingKeys[i];
	    width= XkbKeyGroupsWidth(xkb,key);
	    nClear= width-firstClear;
	    pSyms= XkbKeySymsPtr(xkb,key);
	    for (g=XkbKeyNumGroups(xkb,key)-1;g>=0;g--) {
		if (XkbKeyKeyTypeIndex(xkb,key,g)==type_ndx) {
		    if (nClear>0)
			bzero(&pSyms[g*width+firstClear],nClear*sizeof(KeySym));
		}
	    }
	}
    }
    type->num_levels= new_num_lvls;
    return Success;
}

KeySym *
XkbResizeKeySyms(XkbDescPtr xkb,int key,int needed)
{
register int i,nSyms,nKeySyms;
unsigned nOldSyms;
KeySym	*newSyms;

    if (needed==0) {
	xkb->map->key_sym_map[key].offset= 0;
	return xkb->map->syms;
    }
    nOldSyms= XkbKeyNumSyms(xkb,key);
    if (nOldSyms>=(unsigned)needed) {
	return XkbKeySymsPtr(xkb,key);
    }
    if (xkb->map->size_syms-xkb->map->num_syms>=(unsigned)needed) {
	if (nOldSyms>0) {
	    memcpy(&xkb->map->syms[xkb->map->num_syms],XkbKeySymsPtr(xkb,key),
						nOldSyms*sizeof(KeySym));
	}
	if ((needed-nOldSyms)>0) {
	    bzero(&xkb->map->syms[xkb->map->num_syms+XkbKeyNumSyms(xkb,key)],
					(needed-nOldSyms)*sizeof(KeySym));
	}
	xkb->map->key_sym_map[key].offset = xkb->map->num_syms;
	xkb->map->num_syms+= needed;
	return &xkb->map->syms[xkb->map->key_sym_map[key].offset];
    }
    xkb->map->size_syms+= (needed>32?needed:32);
    newSyms = _XkbTypedCalloc(xkb->map->size_syms,KeySym);
    if (newSyms==NULL)
	return NULL;
    newSyms[0]= NoSymbol;
    nSyms = 1;
    for (i=xkb->min_key_code;i<=(int)xkb->max_key_code;i++) {
	int nCopy;

	nCopy= nKeySyms= XkbKeyNumSyms(xkb,i);
	if ((nKeySyms==0)&&(i!=key))
	    continue;
	if (i==key)
	    nKeySyms= needed;
	if (nCopy!=0)
	   memcpy(&newSyms[nSyms],XkbKeySymsPtr(xkb,i),nCopy*sizeof(KeySym));
	if (nKeySyms>nCopy)
	    bzero(&newSyms[nSyms+nCopy],(nKeySyms-nCopy)*sizeof(KeySym));
	xkb->map->key_sym_map[i].offset = nSyms;
	nSyms+= nKeySyms;
    }
    _XkbFree(xkb->map->syms);
    xkb->map->syms = newSyms;
    xkb->map->num_syms = nSyms;
    return &xkb->map->syms[xkb->map->key_sym_map[key].offset];
}

static unsigned
_ExtendRange(	unsigned int 	old_flags,
		unsigned int	flag,
		KeyCode		newKC,
		KeyCode *	old_min,
		unsigned char *	old_num)
{
    if ((old_flags&flag)==0) {
	old_flags|= flag;
	*old_min= newKC;
	*old_num= 1;
    }
    else {
	int	last= (*old_min)+(*old_num)-1;
	if (newKC<*old_min) {
	    *old_min= newKC;
	    *old_num= (last-newKC)+1;
	}
	else if (newKC>last) {
	    *old_num= (newKC-(*old_min))+1;
	}
    }
    return old_flags;
}

Status
XkbChangeKeycodeRange(	XkbDescPtr	xkb,
			int 		minKC,
			int 		maxKC,
			XkbChangesPtr	changes)
{
int	tmp;

    if ((!xkb)||(minKC<XkbMinLegalKeyCode)||(maxKC>XkbMaxLegalKeyCode))
	return BadValue;
    if (minKC>maxKC)
	return BadMatch;
    if (minKC<xkb->min_key_code) {
	if (changes)
	    changes->map.min_key_code= minKC;
	tmp= xkb->min_key_code-minKC;
	if (xkb->map)  {
	    if (xkb->map->key_sym_map) {
		bzero((char *)&xkb->map->key_sym_map[minKC],
					tmp*sizeof(XkbSymMapRec));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    				XkbKeySymsMask,minKC,
	    					&changes->map.first_key_sym,
	    					&changes->map.num_key_syms);
		}
	    }
	    if (xkb->map->modmap) {
		bzero((char *)&xkb->map->modmap[minKC],tmp);
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    				XkbModifierMapMask,minKC,
	    					&changes->map.first_modmap_key,
	    					&changes->map.num_modmap_keys);
		}
	    }
	}
	if (xkb->server) {
	    if (xkb->server->behaviors) {
		bzero((char *)&xkb->server->behaviors[minKC],
						tmp*sizeof(XkbBehavior));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    			XkbKeyBehaviorsMask,minKC,
    					&changes->map.first_key_behavior,
    					&changes->map.num_key_behaviors);
		}
	    }
	    if (xkb->server->key_acts) {
		bzero((char *)&xkb->server->key_acts[minKC],
						tmp*sizeof(unsigned short));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    			XkbKeyActionsMask,minKC,
    					&changes->map.first_key_act,
    					&changes->map.num_key_acts);
		}
	    }
	    if (xkb->server->vmodmap) {
		bzero((char *)&xkb->server->vmodmap[minKC],
						tmp*sizeof(unsigned short));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    			XkbVirtualModMapMask,minKC,
		    			&changes->map.first_modmap_key,
    					&changes->map.num_vmodmap_keys);
		}
	    }
	}
	if ((xkb->names)&&(xkb->names->keys)) {
	    bzero((char *)&xkb->names->keys[minKC],tmp*sizeof(XkbKeyNameRec));
	    if (changes) {
		changes->names.changed= _ExtendRange(changes->names.changed,
					XkbKeyNamesMask,minKC,
					&changes->names.first_key,
    					&changes->names.num_keys);
	    }
	}
	xkb->min_key_code= minKC;
    }
    if (maxKC>xkb->max_key_code) {
	if (changes)
	    changes->map.max_key_code= maxKC;
	tmp= maxKC-xkb->max_key_code;
	if (xkb->map)  {
	    if (xkb->map->key_sym_map) {
		XkbSymMapRec *prev_key_sym_map = xkb->map->key_sym_map;

		xkb->map->key_sym_map= _XkbTypedRealloc(xkb->map->key_sym_map,
						(maxKC+1),XkbSymMapRec);
		if (!xkb->map->key_sym_map) {
		    _XkbFree(prev_key_sym_map);
		    return BadAlloc;
		}
		bzero((char *)&xkb->map->key_sym_map[xkb->max_key_code],
					tmp*sizeof(XkbSymMapRec));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    				XkbKeySymsMask,maxKC,
	    					&changes->map.first_key_sym,
	    					&changes->map.num_key_syms);
		}
	    }
	    if (xkb->map->modmap) {
		unsigned char *prev_modmap = xkb->map->modmap;

		xkb->map->modmap= _XkbTypedRealloc(xkb->map->modmap,
						(maxKC+1),unsigned char);
		if (!xkb->map->modmap) {
		    _XkbFree(prev_modmap);
		    return BadAlloc;
		}
		bzero((char *)&xkb->map->modmap[xkb->max_key_code],tmp);
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    				XkbModifierMapMask,maxKC,
	    					&changes->map.first_modmap_key,
	    					&changes->map.num_modmap_keys);
		}
	    }
	}
	if (xkb->server) {
	    if (xkb->server->behaviors) {
		XkbBehavior *prev_behaviors = xkb->server->behaviors;

		xkb->server->behaviors=_XkbTypedRealloc(xkb->server->behaviors,
						(maxKC+1),XkbBehavior);
		if (!xkb->server->behaviors) {
		    _XkbFree(prev_behaviors);
		    return BadAlloc;
		}
		bzero((char *)&xkb->server->behaviors[xkb->max_key_code],
						tmp*sizeof(XkbBehavior));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    			XkbKeyBehaviorsMask,maxKC,
    					&changes->map.first_key_behavior,
    					&changes->map.num_key_behaviors);
		}
	    }
	    if (xkb->server->key_acts) {
		unsigned short *prev_key_acts = xkb->server->key_acts;

		xkb->server->key_acts= _XkbTypedRealloc(xkb->server->key_acts,
						(maxKC+1),unsigned short);
		if (!xkb->server->key_acts) {
		    _XkbFree(prev_key_acts);
		    return BadAlloc;
		}
		bzero((char *)&xkb->server->key_acts[xkb->max_key_code],
						tmp*sizeof(unsigned short));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    			XkbKeyActionsMask,maxKC,
    					&changes->map.first_key_act,
    					&changes->map.num_key_acts);
		}
	    }
	    if (xkb->server->vmodmap) {
		unsigned short *prev_vmodmap = xkb->server->vmodmap;

		xkb->server->vmodmap= _XkbTypedRealloc(xkb->server->vmodmap,
						(maxKC+1),unsigned short);
		if (!xkb->server->vmodmap) {
		    _XkbFree(prev_vmodmap);
		    return BadAlloc;
		}
		bzero((char *)&xkb->server->vmodmap[xkb->max_key_code],
						tmp*sizeof(unsigned short));
		if (changes) {
		    changes->map.changed= _ExtendRange(changes->map.changed,
		    			XkbVirtualModMapMask,maxKC,
		    			&changes->map.first_modmap_key,
    					&changes->map.num_vmodmap_keys);
		}
	    }
	}
	if ((xkb->names)&&(xkb->names->keys)) {
	    XkbKeyNameRec *prev_keys = xkb->names->keys;

	    xkb->names->keys= _XkbTypedRealloc(xkb->names->keys,
	    					(maxKC+1),XkbKeyNameRec);
	    if (!xkb->names->keys) {
		_XkbFree(prev_keys);
		return BadAlloc;
	    }
	    bzero((char *)&xkb->names->keys[xkb->max_key_code],
	    					tmp*sizeof(XkbKeyNameRec));
	    if (changes) {
		changes->names.changed= _ExtendRange(changes->names.changed,
					XkbKeyNamesMask,maxKC,
					&changes->names.first_key,
    					&changes->names.num_keys);
	    }
	}
	xkb->max_key_code= maxKC;
    }
    return Success;
}

XkbAction *
XkbResizeKeyActions(XkbDescPtr xkb,int key,int needed)
{
register int i,nActs;
XkbAction *newActs;

    if (needed==0) {
	xkb->server->key_acts[key]= 0;
	return NULL;
    }
    if (XkbKeyHasActions(xkb,key)&&(XkbKeyNumSyms(xkb,key)>=(unsigned)needed))
	return XkbKeyActionsPtr(xkb,key);
    if (xkb->server->size_acts-xkb->server->num_acts>=(unsigned)needed) {
	xkb->server->key_acts[key]= xkb->server->num_acts;
	xkb->server->num_acts+= needed;
	return &xkb->server->acts[xkb->server->key_acts[key]];
    }
    xkb->server->size_acts= xkb->server->num_acts+needed+8;
    newActs = _XkbTypedCalloc(xkb->server->size_acts,XkbAction);
    if (newActs==NULL)
	return NULL;
    newActs[0].type = XkbSA_NoAction;
    nActs = 1;
    for (i=xkb->min_key_code;i<=(int)xkb->max_key_code;i++) {
	int nKeyActs,nCopy;

	if ((xkb->server->key_acts[i]==0)&&(i!=key))
	    continue;

	nCopy= nKeyActs= XkbKeyNumActions(xkb,i);
	if (i==key) {
	    nKeyActs= needed;
	    if (needed<nCopy)
		nCopy= needed;
	}

	if (nCopy>0)
	    memcpy(&newActs[nActs],XkbKeyActionsPtr(xkb,i),
						nCopy*sizeof(XkbAction));
	if (nCopy<nKeyActs)
	    bzero(&newActs[nActs+nCopy],(nKeyActs-nCopy)*sizeof(XkbAction));
	xkb->server->key_acts[i]= nActs;
	nActs+= nKeyActs;
    }
    _XkbFree(xkb->server->acts);
    xkb->server->acts = newActs;
    xkb->server->num_acts= nActs;
    return &xkb->server->acts[xkb->server->key_acts[key]];
}

void
XkbFreeClientMap(XkbDescPtr xkb,unsigned what,Bool freeMap)
{
XkbClientMapPtr	map;

    if ((xkb==NULL)||(xkb->map==NULL))
	return;
    if (freeMap)
	what= XkbAllClientInfoMask;
    map= xkb->map;
    if (what&XkbKeyTypesMask) {
	if (map->types!=NULL) {
	    if (map->num_types>0) {
		register int 	i;
		XkbKeyTypePtr	type;
		for (i=0,type=map->types;i<map->num_types;i++,type++) {
		    if (type->map!=NULL) {
			_XkbFree(type->map);
			type->map= NULL;
		    }
		    if (type->preserve!=NULL) {
			_XkbFree(type->preserve);
			type->preserve= NULL;
		    }
		    type->map_count= 0;
		    if (type->level_names!=NULL) {
			_XkbFree(type->level_names);
			type->level_names= NULL;
		    }
		}
	    }
	    _XkbFree(map->types);
	    map->num_types= map->size_types= 0;
	    map->types= NULL;
	}
    }
    if (what&XkbKeySymsMask) {
	if (map->key_sym_map!=NULL) {
	    _XkbFree(map->key_sym_map);
	    map->key_sym_map= NULL;
	}
	if (map->syms!=NULL) {
	    _XkbFree(map->syms);
	    map->size_syms= map->num_syms= 0;
	    map->syms= NULL;
	}
    }
    if ((what&XkbModifierMapMask)&&(map->modmap!=NULL)) {
	_XkbFree(map->modmap);
	map->modmap= NULL;
    }
    if (freeMap) {
	_XkbFree(xkb->map);
	xkb->map= NULL;
    }
    return;
}

void
XkbFreeServerMap(XkbDescPtr xkb,unsigned what,Bool freeMap)
{
XkbServerMapPtr	map;

    if ((xkb==NULL)||(xkb->server==NULL))
	return;
    if (freeMap)
	what= XkbAllServerInfoMask;
    map= xkb->server;
    if ((what&XkbExplicitComponentsMask)&&(map->explicit!=NULL)) {
	_XkbFree(map->explicit);
	map->explicit= NULL;
    }
    if (what&XkbKeyActionsMask) {
	if (map->key_acts!=NULL) {
	    _XkbFree(map->key_acts);
	    map->key_acts= NULL;
	}
	if (map->acts!=NULL) {
	    _XkbFree(map->acts);
	    map->num_acts= map->size_acts= 0;
	    map->acts= NULL;
	}
    }
    if ((what&XkbKeyBehaviorsMask)&&(map->behaviors!=NULL)) {
	_XkbFree(map->behaviors);
	map->behaviors= NULL;
    }
    if ((what&XkbVirtualModMapMask)&&(map->vmodmap!=NULL)) {
	_XkbFree(map->vmodmap);
	map->vmodmap= NULL;
    }

    if (freeMap) {
	_XkbFree(xkb->server);
	xkb->server= NULL;
    }
    return;
}

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