blender-archive/source/blender/blenkernel/intern/mesh.c

/*  mesh.c
 *
 *  
 * 
 * $Id$
 *
 * ***** BEGIN GPL/BL DUAL LICENSE BLOCK *****
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version. The Blender
 * Foundation also sells licenses for use in proprietary software under
 * the Blender License.  See http://www.blender.org/BL/ for information
 * about this.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software Foundation,
 * Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
 *
 * The Original Code is Copyright (C) 2001-2002 by NaN Holding BV.
 * All rights reserved.
 *
 * The Original Code is: all of this file.
 *
 * Contributor(s): none yet.
 *
 * ***** END GPL/BL DUAL LICENSE BLOCK *****
 */

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <math.h>

#include "MEM_guardedalloc.h"

#include "DNA_ID.h"
#include "DNA_curve_types.h"
#include "DNA_material_types.h"
#include "DNA_object_types.h"
#include "DNA_image_types.h"
#include "DNA_key_types.h"
#include "DNA_mesh_types.h"
#include "DNA_meshdata_types.h"
#include "DNA_ipo_types.h"

#include "BDR_sculptmode.h"

#include "BKE_depsgraph.h"
#include "BKE_main.h"
#include "BKE_DerivedMesh.h"
#include "BKE_global.h"
#include "BKE_mesh.h"
#include "BKE_subsurf.h"
#include "BKE_displist.h"
#include "BKE_library.h"
#include "BKE_material.h"
#include "BKE_key.h"
/* these 2 are only used by conversion functions */
#include "BKE_curve.h"
/* -- */
#include "BKE_object.h"
#include "BKE_utildefines.h"
#include "BKE_bad_level_calls.h"

#ifdef WITH_VERSE
#include "BKE_verse.h"
#endif

#include "BLI_blenlib.h"
#include "BLI_editVert.h"
#include "BLI_arithb.h"

#include "multires.h"



int update_realtime_texture(TFace *tface, double time)
{
	Image *ima;
	int	inc = 0;
	float	diff;
	int	newframe;

	ima = tface->tpage;

	if (!ima)
		return 0;

	if (ima->lastupdate<0)
		ima->lastupdate = 0;

	if (ima->lastupdate>time)
		ima->lastupdate=(float)time;

	if(ima->tpageflag & IMA_TWINANIM) {
		if(ima->twend >= ima->xrep*ima->yrep) ima->twend= ima->xrep*ima->yrep-1;
		
		/* check: is the bindcode not in the array? Then free. (still to do) */
		
		diff = (float)(time-ima->lastupdate);

		inc = (int)(diff*(float)ima->animspeed);

		ima->lastupdate+=((float)inc/(float)ima->animspeed);

		newframe = ima->lastframe+inc;

		if (newframe > (int)ima->twend)
			newframe = (int)ima->twsta-1 + (newframe-ima->twend)%(ima->twend-ima->twsta);

		ima->lastframe = newframe;
	}
	return inc;
}

/* Note: unlinking is called when me->id.us is 0, question remains how
 * much unlinking of Library data in Mesh should be done... probably
 * we need a more generic method, like the expand() functions in
 * readfile.c */

void unlink_mesh(Mesh *me)
{
	int a;
	
	if(me==0) return;
	
	for(a=0; a<me->totcol; a++) {
		if(me->mat[a]) me->mat[a]->id.us--;
		me->mat[a]= 0;
	}

	if(me->key) {
	   	me->key->id.us--;
		if (me->key->id.us == 0 && me->key->ipo )
			me->key->ipo->id.us--;
	}
	me->key= 0;
	
	if(me->texcomesh) me->texcomesh= 0;
}


/* do not free mesh itself */
void free_mesh(Mesh *me)
{
	unlink_mesh(me);

	if(me->pv) {
		if(me->pv->vert_map) MEM_freeN(me->pv->vert_map);
		if(me->pv->edge_map) MEM_freeN(me->pv->edge_map);
		if(me->pv->old_faces) MEM_freeN(me->pv->old_faces);
		if(me->pv->old_edges) MEM_freeN(me->pv->old_edges);
		MEM_freeN(me->pv);
	}

	if(me->mvert) MEM_freeN(me->mvert);
	if(me->medge) MEM_freeN(me->medge);
	if(me->mface) MEM_freeN(me->mface);
	
	if(me->tface) MEM_freeN(me->tface);
	if(me->dvert) free_dverts(me->dvert, me->totvert);
	if(me->mcol) MEM_freeN(me->mcol);
	if(me->msticky) MEM_freeN(me->msticky);

	if(me->mat) MEM_freeN(me->mat);
	
	if(me->bb) MEM_freeN(me->bb);
	if(me->mselect) MEM_freeN(me->mselect);

	if(me->mr) multires_free(me);
}

void copy_dverts(MDeformVert *dst, MDeformVert *src, int copycount)
{
	/* Assumes dst is already set up */
	int i;

	if (!src || !dst)
		return;

	memcpy (dst, src, copycount * sizeof(MDeformVert));
	
	for (i=0; i<copycount; i++){
		if (src[i].dw){
			dst[i].dw = MEM_callocN (sizeof(MDeformWeight)*src[i].totweight, "copy_deformWeight");
			memcpy (dst[i].dw, src[i].dw, sizeof (MDeformWeight)*src[i].totweight);
		}
	}

}
void free_dverts(MDeformVert *dvert, int totvert)
{
	/* Instead of freeing the verts directly,
	call this function to delete any special
	vert data */
	int	i;

	if (!dvert)
		return;

	/* Free any special data from the verts */
	for (i=0; i<totvert; i++){
		if (dvert[i].dw) MEM_freeN (dvert[i].dw);
	}
	MEM_freeN (dvert);
}

Mesh *add_mesh()
{
	Mesh *me;
	
	me= alloc_libblock(&G.main->mesh, ID_ME, "Mesh");
	
	me->size[0]= me->size[1]= me->size[2]= 1.0;
	me->smoothresh= 30;
	me->texflag= AUTOSPACE;
	me->flag= ME_TWOSIDED;
	me->bb= unit_boundbox();

#ifdef WITH_VERSE
	me->vnode = NULL;
#endif

	return me;
}

Mesh *copy_mesh(Mesh *me)
{
	Mesh *men;
	int a;
	
	men= copy_libblock(me);
	
	men->mat= MEM_dupallocN(me->mat);
	for(a=0; a<men->totcol; a++) {
		id_us_plus((ID *)men->mat[a]);
	}
	id_us_plus((ID *)men->texcomesh);

	men->mvert= MEM_dupallocN(me->mvert);
	men->medge= MEM_dupallocN(me->medge);
	men->mface= MEM_dupallocN(me->mface);
	men->tface= MEM_dupallocN(me->tface);
	men->dface= NULL;
	men->mselect= NULL;
	
	if (me->dvert){
		men->dvert = MEM_mallocN (sizeof (MDeformVert)*me->totvert, "MDeformVert");
		copy_dverts(men->dvert, me->dvert, me->totvert);
	}
	if (me->tface){
		/* ensure indirect linked data becomes lib-extern */
		TFace *tface= me->tface;
		for(a=0; a<me->totface; a++, tface++)
			if(tface->tpage)
				id_lib_extern(tface->tpage);
	}
	men->mcol= MEM_dupallocN(me->mcol);
	men->msticky= MEM_dupallocN(me->msticky);

	men->bb= MEM_dupallocN(men->bb);
	
	men->key= copy_key(me->key);
	if(men->key) men->key->from= (ID *)men;

#ifdef WITH_VERSE
	men->vnode = NULL;
#endif	

	return men;
}

void make_local_tface(Mesh *me)
{
	TFace *tface;
	Image *ima;
	int a;
	
	if(me->tface==0) return;
	
	a= me->totface;
	tface= me->tface;
	while(a--) {
		
		/* special case: ima always local immediately */
		if(tface->tpage) {
			ima= tface->tpage;
			if(ima->id.lib) {
				ima->id.lib= 0;
				ima->id.flag= LIB_LOCAL;
				new_id(0, (ID *)ima, 0);
			}
		}
		tface++;
	}
	
}

void make_local_mesh(Mesh *me)
{
	Object *ob;
	Mesh *men;
	int local=0, lib=0;

	/* - only lib users: do nothing
	    * - only local users: set flag
	    * - mixed: make copy
	    */
	
	if(me->id.lib==0) return;
	if(me->id.us==1) {
		me->id.lib= 0;
		me->id.flag= LIB_LOCAL;
		new_id(0, (ID *)me, 0);
		
		if(me->tface) make_local_tface(me);
		
		return;
	}
	
	ob= G.main->object.first;
	while(ob) {
		if( me==get_mesh(ob) ) {
			if(ob->id.lib) lib= 1;
			else local= 1;
		}
		ob= ob->id.next;
	}
	
	if(local && lib==0) {
		me->id.lib= 0;
		me->id.flag= LIB_LOCAL;
		new_id(0, (ID *)me, 0);
		
		if(me->tface) make_local_tface(me);
		
	}
	else if(local && lib) {
		men= copy_mesh(me);
		men->id.us= 0;
		
		ob= G.main->object.first;
		while(ob) {
			if( me==get_mesh(ob) ) {				
				if(ob->id.lib==0) {
					set_mesh(ob, men);
				}
			}
			ob= ob->id.next;
		}
	}
}

void boundbox_mesh(Mesh *me, float *loc, float *size)
{
	MVert *mvert;
	BoundBox *bb;
	float min[3], max[3];
	float mloc[3], msize[3];
	int a;
	
	if(me->bb==0) me->bb= MEM_callocN(sizeof(BoundBox), "boundbox");
	bb= me->bb;
	
	INIT_MINMAX(min, max);

	if (!loc) loc= mloc;
	if (!size) size= msize;
	
	mvert= me->mvert;
	for(a=0; a<me->totvert; a++, mvert++) {
		DO_MINMAX(mvert->co, min, max);
	}

	if(!me->totvert) {
		min[0] = min[1] = min[2] = -1.0f;
		max[0] = max[1] = max[2] = 1.0f;
	}

	loc[0]= (min[0]+max[0])/2.0f;
	loc[1]= (min[1]+max[1])/2.0f;
	loc[2]= (min[2]+max[2])/2.0f;
		
	size[0]= (max[0]-min[0])/2.0f;
	size[1]= (max[1]-min[1])/2.0f;
	size[2]= (max[2]-min[2])/2.0f;
	
	boundbox_set_from_min_max(bb, min, max);
}

void tex_space_mesh(Mesh *me)
{
	KeyBlock *kb;
	float *fp, loc[3], size[3], min[3], max[3];
	int a;

	boundbox_mesh(me, loc, size);

	if(me->texflag & AUTOSPACE) {
		if(me->key) {
			kb= me->key->refkey;
			if (kb) {
				
				INIT_MINMAX(min, max);
				
				fp= kb->data;
				for(a=0; a<kb->totelem; a++, fp+=3) {	
					DO_MINMAX(fp, min, max);
				}
				if(kb->totelem) {
					loc[0]= (min[0]+max[0])/2.0f; loc[1]= (min[1]+max[1])/2.0f; loc[2]= (min[2]+max[2])/2.0f;
					size[0]= (max[0]-min[0])/2.0f; size[1]= (max[1]-min[1])/2.0f; size[2]= (max[2]-min[2])/2.0f;
				}
				else {
					loc[0]= loc[1]= loc[2]= 0.0;
					size[0]= size[1]= size[2]= 0.0;
				}
				
			}
		}

		for (a=0; a<3; a++) {
			if(size[a]==0.0) size[a]= 1.0;
			else if(size[a]>0.0 && size[a]<0.00001) size[a]= 0.00001;
			else if(size[a]<0.0 && size[a]> -0.00001) size[a]= -0.00001;
		}

		VECCOPY(me->loc, loc);
		VECCOPY(me->size, size);
		me->rot[0]= me->rot[1]= me->rot[2]= 0.0;
	}
}

BoundBox *mesh_get_bb(Mesh *me)
{
	if (!me->bb) {
		tex_space_mesh(me);
	}

	return me->bb;
}

void mesh_get_texspace(Mesh *me, float *loc_r, float *rot_r, float *size_r)
{
	if (!me->bb) {
		tex_space_mesh(me);
	}

	if (loc_r) VECCOPY(loc_r, me->loc);
	if (rot_r) VECCOPY(rot_r, me->rot);
	if (size_r) VECCOPY(size_r, me->size);
}

static float *make_orco_mesh_internal(Object *ob, int render)
{
	Mesh *me = ob->data;
	float (*orcoData)[3];
	int a, totvert;
	float loc[3], size[3];
	DerivedMesh *dm;
	float (*vcos)[3] = MEM_callocN(sizeof(*vcos)*me->totvert, "orco mesh");

		/* Get appropriate vertex coordinates */

	if(me->key && me->texcomesh==0 && me->key->refkey) {
		KeyBlock *kb= me->key->refkey;
		float *fp= kb->data;
		totvert= MIN2(kb->totelem, me->totvert);

		for(a=0; a<totvert; a++, fp+=3) {
			vcos[a][0]= fp[0];
			vcos[a][1]= fp[1];
			vcos[a][2]= fp[2];
		}
	}
	else {
		Mesh *tme = me->texcomesh?me->texcomesh:me;
		MVert *mvert = tme->mvert;
		totvert = MIN2(tme->totvert, me->totvert);

		for(a=0; a<totvert; a++, mvert++) {
			vcos[a][0]= mvert->co[0];
			vcos[a][1]= mvert->co[1];
			vcos[a][2]= mvert->co[2];
		}
	}

		/* Apply orco-changing modifiers */

	if (render) {
		dm = mesh_create_derived_no_deform_render(ob, vcos);
	} else {
		dm = mesh_create_derived_no_deform(ob, vcos);
	}
	totvert = dm->getNumVerts(dm);

	orcoData = MEM_mallocN(sizeof(*orcoData)*totvert, "orcoData");
	dm->getVertCos(dm, orcoData);
	dm->release(dm);
	MEM_freeN(vcos);

	mesh_get_texspace(me->texcomesh?me->texcomesh:me, loc, NULL, size);

	for(a=0; a<totvert; a++) {
		float *co = orcoData[a];
		co[0] = (co[0]-loc[0])/size[0];
		co[1] = (co[1]-loc[1])/size[1];
		co[2] = (co[2]-loc[2])/size[2];
	}

	return (float*) orcoData;
}

float *mesh_create_orco_render(Object *ob) 
{
	return make_orco_mesh_internal(ob, 1);
}

float *mesh_create_orco(Object *ob)
{
	return make_orco_mesh_internal(ob, 0);
}

	/* rotates the vertices of a face in case v[2] or v[3] (vertex index) is = 0. */
#define UVSWAP(t, s) { SWAP(float, t[0], s[0]); SWAP(float, t[1], s[1]); }
void test_index_face(MFace *mface, MCol *mc, TFace *tface, int nr)
{
	/* first test if the face is legal */

	if(mface->v3 && mface->v3==mface->v4) {
		mface->v4= 0;
		nr--;
	}
	if(mface->v2 && mface->v2==mface->v3) {
		mface->v3= mface->v4;
		mface->v4= 0;
		nr--;
	}
	if(mface->v1==mface->v2) {
		mface->v2= mface->v3;
		mface->v3= mface->v4;
		mface->v4= 0;
		nr--;
	}

	/* prevent a zero at wrong index location */
	if(nr==3) {
		if(mface->v3==0) {
			SWAP(int, mface->v1, mface->v2);
			SWAP(int, mface->v2, mface->v3);

			if (tface) {
				UVSWAP(tface->uv[0], tface->uv[1]);
				UVSWAP(tface->uv[1], tface->uv[2]);
				SWAP(unsigned int, tface->col[0], tface->col[1]);
				SWAP(unsigned int, tface->col[1], tface->col[2]);
			}

			if (mc) {
				SWAP(MCol, mc[0], mc[1]);
				SWAP(MCol, mc[1], mc[2]);
			}
		}
	}
	else if(nr==4) {
		if(mface->v3==0 || mface->v4==0) {
			SWAP(int, mface->v1, mface->v3);
			SWAP(int, mface->v2, mface->v4);


			if (tface) {
				UVSWAP(tface->uv[0], tface->uv[2]);
				UVSWAP(tface->uv[1], tface->uv[3]);
				SWAP(unsigned int, tface->col[0], tface->col[2]);
				SWAP(unsigned int, tface->col[1], tface->col[3]);
			}

			if (mc) {
				SWAP(MCol, mc[0], mc[2]);
				SWAP(MCol, mc[1], mc[3]);
			}
		}
	}
}

Mesh *get_mesh(Object *ob)
{
	
	if(ob==0) return 0;
	if(ob->type==OB_MESH) return ob->data;
	else return 0;
}

void set_mesh(Object *ob, Mesh *me)
{
	Mesh *old=0;
	
	if(ob==0) return;
	
	if(ob->type==OB_MESH) {
		old= ob->data;
		old->id.us--;
		ob->data= me;
		id_us_plus((ID *)me);
	}
	
	test_object_materials((ID *)me);
}

/* ************** make edges in a Mesh, for outside of editmode */

struct edgesort {
	int v1, v2;
	short is_loose, is_draw;
};

/* edges have to be added with lowest index first for sorting */
static void to_edgesort(struct edgesort *ed, int v1, int v2, short is_loose, short is_draw)
{
	if(v1<v2) {
		ed->v1= v1; ed->v2= v2;
	}
	else {
		ed->v1= v2; ed->v2= v1;
	}
	ed->is_loose= is_loose;
	ed->is_draw= is_draw;
}

static int vergedgesort(const void *v1, const void *v2)
{
	const struct edgesort *x1=v1, *x2=v2;

	if( x1->v1 > x2->v1) return 1;
	else if( x1->v1 < x2->v1) return -1;
	else if( x1->v2 > x2->v2) return 1;
	else if( x1->v2 < x2->v2) return -1;
	
	return 0;
}


void make_edges(Mesh *me, int old)
{
	MFace *mface;
	MEdge *medge;
	struct edgesort *edsort, *ed;
	int a, totedge=0, final=0;
	
	/* we put all edges in array, sort them, and detect doubles that way */
	
	for(a= me->totface, mface= me->mface; a>0; a--, mface++) {
		if(mface->v4) totedge+=4;
		else if(mface->v3) totedge+=3;
		else totedge+=1;
	}
	
	if(totedge==0) {
			/* flag that mesh has edges */
		me->medge = MEM_callocN(0, "make mesh edges");
		me->totedge = 0;
		return;
	}
	
	ed= edsort= MEM_mallocN(totedge*sizeof(struct edgesort), "edgesort");
	
	for(a= me->totface, mface= me->mface; a>0; a--, mface++) {
		to_edgesort(ed++, mface->v1, mface->v2, !mface->v3, mface->edcode & ME_V1V2);
		if(mface->v4) {
			to_edgesort(ed++, mface->v2, mface->v3, 0, mface->edcode & ME_V2V3);
			to_edgesort(ed++, mface->v3, mface->v4, 0, mface->edcode & ME_V3V4);
			to_edgesort(ed++, mface->v4, mface->v1, 0, mface->edcode & ME_V4V1);
		}
		else if(mface->v3) {
			to_edgesort(ed++, mface->v2, mface->v3, 0, mface->edcode & ME_V2V3);
			to_edgesort(ed++, mface->v3, mface->v1, 0, mface->edcode & ME_V3V1);
		}
	}
	
	qsort(edsort, totedge, sizeof(struct edgesort), vergedgesort);
	
	/* count final amount */
	for(a=totedge, ed=edsort; a>1; a--, ed++) {
		/* edge is unique when it differs from next edge, or is last */
		if(ed->v1 != (ed+1)->v1 || ed->v2 != (ed+1)->v2) final++;
	}
	final++;
	
	medge= me->medge= MEM_callocN(final*sizeof(MEdge), "make mesh edges");
	me->totedge= final;
	
	for(a=totedge, ed=edsort; a>1; a--, ed++) {
		/* edge is unique when it differs from next edge, or is last */
		if(ed->v1 != (ed+1)->v1 || ed->v2 != (ed+1)->v2) {
			medge->v1= ed->v1;
			medge->v2= ed->v2;
			if(old==0 || ed->is_draw) medge->flag= ME_EDGEDRAW|ME_EDGERENDER;
			if(ed->is_loose) medge->flag|= ME_LOOSEEDGE;
			medge++;
		}
		else {
			/* equal edge, we merge the drawflag */
			(ed+1)->is_draw |= ed->is_draw;
		}
	}
	/* last edge */
	medge->v1= ed->v1;
	medge->v2= ed->v2;
	medge->flag= ME_EDGEDRAW;
	if(ed->is_loose) medge->flag|= ME_LOOSEEDGE;
	medge->flag |= ME_EDGERENDER;

	MEM_freeN(edsort);

	mesh_strip_loose_faces(me);
}

void mesh_strip_loose_faces(Mesh *me)
{
	int a,b;

	for (a=b=0; a<me->totface; a++) {
		if (me->mface[a].v3) {
			if (a!=b) {
				memcpy(&me->mface[b],&me->mface[a],sizeof(me->mface[b]));
				if (me->tface) memcpy(&me->tface[b],&me->tface[a],sizeof(me->tface[b]));
				if (me->mcol) memcpy(&me->mcol[b*4],&me->mcol[a*4],sizeof(me->mcol[b])*4);
			}
			b++;
		}
	}
	me->totface = b;
}


void mball_to_mesh(ListBase *lb, Mesh *me)
{
	DispList *dl;
	MVert *mvert;
	MFace *mface;
	float *nors, *verts;
	int a, *index;
	
	dl= lb->first;
	if(dl==0) return;

	if(dl->type==DL_INDEX4) {
		me->flag= ME_NOPUNOFLIP;
		me->totvert= dl->nr;
		me->totface= dl->parts;
		
		me->mvert=mvert= MEM_callocN(dl->nr*sizeof(MVert), "mverts");
		a= dl->nr;
		nors= dl->nors;
		verts= dl->verts;
		while(a--) {
			VECCOPY(mvert->co, verts);
			mvert->no[0]= (short int)(nors[0]*32767.0);
			mvert->no[1]= (short int)(nors[1]*32767.0);
			mvert->no[2]= (short int)(nors[2]*32767.0);
			mvert++;
			nors+= 3;
			verts+= 3;
		}
		
		me->mface=mface= MEM_callocN(dl->parts*sizeof(MFace), "mface");
		a= dl->parts;
		index= dl->index;
		while(a--) {
			mface->v1= index[0];
			mface->v2= index[1];
			mface->v3= index[2];
			mface->v4= index[3];
			mface->flag = ME_SMOOTH;
			
			mface++;
			index+= 4;
		}
	}	
}

void nurbs_to_mesh(Object *ob)
{
	Object *ob1;
	DispList *dl;
	Mesh *me;
	Curve *cu;
	MVert *mvert;
	MFace *mface;
	float *data;
	int a, b, ofs, vertcount, startvert, totvert=0, totvlak=0;
	int p1, p2, p3, p4, *index;

	cu= ob->data;

	/* count */
	dl= cu->disp.first;
	while(dl) {
		if(dl->type==DL_SEGM) {
			totvert+= dl->parts*dl->nr;
			totvlak+= dl->parts*(dl->nr-1);
		}
		else if(dl->type==DL_POLY) {
			/* cyclic polys are filled. except when 3D */
			if(cu->flag & CU_3D) {
				totvert+= dl->parts*dl->nr;
				totvlak+= dl->parts*dl->nr;
			}
		}
		else if(dl->type==DL_SURF) {
			totvert+= dl->parts*dl->nr;
			totvlak+= (dl->parts-1+((dl->flag & DL_CYCL_V)==2))*(dl->nr-1+(dl->flag & DL_CYCL_U));
		}
		else if(dl->type==DL_INDEX3) {
			totvert+= dl->nr;
			totvlak+= dl->parts;
		}
		dl= dl->next;
	}
	if(totvert==0) {
		error("can't convert");
		return;
	}

	/* make mesh */
	me= add_mesh();
	me->totvert= totvert;
	me->totface= totvlak;

	me->totcol= cu->totcol;
	me->mat= cu->mat;
	cu->mat= 0;
	cu->totcol= 0;

	mvert=me->mvert= MEM_callocN(me->totvert*sizeof(MVert), "cumesh1");
	mface=me->mface= MEM_callocN(me->totface*sizeof(MFace), "cumesh2");

	/* verts and faces */
	vertcount= 0;

	dl= cu->disp.first;
	while(dl) {
		if(dl->type==DL_SEGM) {
			startvert= vertcount;
			a= dl->parts*dl->nr;
			data= dl->verts;
			while(a--) {
				VECCOPY(mvert->co, data);
				data+=3;
				vertcount++;
				mvert++;
			}

			for(a=0; a<dl->parts; a++) {
				ofs= a*dl->nr;
				for(b=1; b<dl->nr; b++) {
					mface->v1= startvert+ofs+b-1;
					mface->v2= startvert+ofs+b;
					mface++;
				}
			}

		}
		else if(dl->type==DL_POLY) {
			/* 3d polys are not filled */
			if(cu->flag & CU_3D) {
				startvert= vertcount;
				a= dl->parts*dl->nr;
				data= dl->verts;
				while(a--) {
					VECCOPY(mvert->co, data);
					data+=3;
					vertcount++;
					mvert++;
				}
	
				for(a=0; a<dl->parts; a++) {
					ofs= a*dl->nr;
					for(b=0; b<dl->nr; b++) {
						mface->v1= startvert+ofs+b;
						if(b==dl->nr-1) mface->v2= startvert+ofs;
						else mface->v2= startvert+ofs+b+1;
						mface++;
					}
				}
			}
		}
		else if(dl->type==DL_INDEX3) {
			startvert= vertcount;
			a= dl->nr;
			data= dl->verts;
			while(a--) {
				VECCOPY(mvert->co, data);
				data+=3;
				vertcount++;
				mvert++;
			}

			a= dl->parts;
			index= dl->index;
			while(a--) {
				mface->v1= startvert+index[0];
				mface->v2= startvert+index[1];
				mface->v3= startvert+index[2];
				mface->v4= 0;
				test_index_face(mface, NULL, NULL, 3);
				
				mface++;
				index+= 3;
			}
	
	
		}
		else if(dl->type==DL_SURF) {
			startvert= vertcount;
			a= dl->parts*dl->nr;
			data= dl->verts;
			while(a--) {
				VECCOPY(mvert->co, data);
				data+=3;
				vertcount++;
				mvert++;
			}

			for(a=0; a<dl->parts; a++) {

				if( (dl->flag & DL_CYCL_V)==0 && a==dl->parts-1) break;

				if(dl->flag & DL_CYCL_U) {			/* p2 -> p1 -> */
					p1= startvert+ dl->nr*a;	/* p4 -> p3 -> */
					p2= p1+ dl->nr-1;		/* -----> next row */
					p3= p1+ dl->nr;
					p4= p2+ dl->nr;
					b= 0;
				}
				else {
					p2= startvert+ dl->nr*a;
					p1= p2+1;
					p4= p2+ dl->nr;
					p3= p1+ dl->nr;
					b= 1;
				}
				if( (dl->flag & DL_CYCL_V) && a==dl->parts-1) {
					p3-= dl->parts*dl->nr;
					p4-= dl->parts*dl->nr;
				}

				for(; b<dl->nr; b++) {
					mface->v1= p1;
					mface->v2= p3;
					mface->v3= p4;
					mface->v4= p2;
					mface->mat_nr= (unsigned char)dl->col;
					test_index_face(mface, NULL, NULL, 4);
					mface++;

					p4= p3; 
					p3++;
					p2= p1; 
					p1++;
				}
			}

		}

		dl= dl->next;
	}

	make_edges(me, 0);	// all edges
	mesh_strip_loose_faces(me);

	if(ob->data) {
		free_libblock(&G.main->curve, ob->data);
	}
	ob->data= me;
	ob->type= OB_MESH;
	
	/* other users */
	ob1= G.main->object.first;
	while(ob1) {
		if(ob1->data==cu) {
			ob1->type= OB_MESH;
		
			ob1->data= ob->data;
			id_us_plus((ID *)ob->data);
		}
		ob1= ob1->id.next;
	}

}

MCol *tface_to_mcol_p(TFace *tface, int totface)
{
	unsigned int *mcol, *mcoldata;
	int a;
	
	mcol= mcoldata= MEM_mallocN(4*sizeof(int)*totface, "nepmcol");
	
	a= totface;
	while(a--) {
		memcpy(mcol, tface->col, 16);
		mcol+= 4;
		tface++;
	}

	return (MCol*) mcoldata;
}

void tface_to_mcol(Mesh *me)
{
	me->mcol = tface_to_mcol_p(me->tface, me->totface);
}

void mcol_to_tface(Mesh *me, int freedata)
{
	TFace *tface;
	unsigned int *mcol;
	int a;
	
	a= me->totface;
	tface= me->tface;
	mcol= (unsigned int *)me->mcol;
	while(a--) {
		memcpy(tface->col, mcol, 16);
		mcol+= 4;
		tface++;
	}
	
	if(freedata) {
		MEM_freeN(me->mcol);
		me->mcol= 0;
	}
}

void mesh_delete_material_index(Mesh *me, int index) {
	int i;

	for (i=0; i<me->totface; i++) {
		MFace *mf = &((MFace*) me->mface)[i];
		if (mf->mat_nr && mf->mat_nr>=index) 
			mf->mat_nr--;
	}
}

void mesh_set_smooth_flag(Object *meshOb, int enableSmooth) {
	Mesh *me = meshOb->data;
	int i;

	for (i=0; i<me->totface; i++) {
		MFace *mf = &((MFace*) me->mface)[i];

		if (enableSmooth) {
			mf->flag |= ME_SMOOTH;
		} else {
			mf->flag &= ~ME_SMOOTH;
		}
	}

	DAG_object_flush_update(G.scene, meshOb, OB_RECALC_DATA);
}

void mesh_calc_normals(MVert *mverts, int numVerts, MFace *mfaces, int numFaces, float **faceNors_r) 
{
	float (*tnorms)[3]= MEM_callocN(numVerts*sizeof(*tnorms), "tnorms");
	float *fnors= MEM_mallocN(sizeof(*fnors)*3*numFaces, "meshnormals");
	int i;
	
	for (i=0; i<numFaces; i++) {
		MFace *mf= &mfaces[i];
		float *f_no= &fnors[i*3];

		if (mf->v4)
			CalcNormFloat4(mverts[mf->v1].co, mverts[mf->v2].co, mverts[mf->v3].co, mverts[mf->v4].co, f_no);
		else
			CalcNormFloat(mverts[mf->v1].co, mverts[mf->v2].co, mverts[mf->v3].co, f_no);
		
		VecAddf(tnorms[mf->v1], tnorms[mf->v1], f_no);
		VecAddf(tnorms[mf->v2], tnorms[mf->v2], f_no);
		VecAddf(tnorms[mf->v3], tnorms[mf->v3], f_no);
		if (mf->v4)
			VecAddf(tnorms[mf->v4], tnorms[mf->v4], f_no);
	}
	for (i=0; i<numVerts; i++) {
		MVert *mv= &mverts[i];
		float *no= tnorms[i];
		
		if (Normalise(no)==0.0) {
			VECCOPY(no, mv->co);
			Normalise(no);
		}

		mv->no[0]= (short)(no[0]*32767.0);
		mv->no[1]= (short)(no[1]*32767.0);
		mv->no[2]= (short)(no[2]*32767.0);
	}
	
	MEM_freeN(tnorms);

	if (faceNors_r) {
		*faceNors_r = fnors;
	} else {
		MEM_freeN(fnors);
	}
}

float (*mesh_getVertexCos(Mesh *me, int *numVerts_r))[3]
{
#ifdef WITH_VERSE
	if(me->vnode) {
		struct VLayer *vlayer;
		struct VerseVert *vvert;
		unsigned int i, numVerts;
		float (*cos)[3];

		vlayer = find_verse_layer_type((VGeomData*)((VNode*)me->vnode)->data, VERTEX_LAYER);

		vvert = vlayer->dl.lb.first;
		numVerts = vlayer->dl.da.count;
		cos = MEM_mallocN(sizeof(*cos)*numVerts, "verse_vertexcos");

		for(i=0; i<numVerts && vvert; vvert = vvert->next, i++) {
			VECCOPY(cos[i], vvert->co);
		}

		return cos;
	}
	else {
#endif
		int i, numVerts = me->totvert;
		float (*cos)[3] = MEM_mallocN(sizeof(*cos)*numVerts, "vertexcos1");
        
		if (numVerts_r) *numVerts_r = numVerts;
		for (i=0; i<numVerts; i++) {
			VECCOPY(cos[i], me->mvert[i].co);
		}
        
		return cos;
#ifdef WITH_VERSE
	}
#endif
}

/* UvVertMap */

struct UvVertMap {
	struct UvMapVert **vert;
	struct UvMapVert *buf;
};

UvVertMap *make_uv_vert_map(struct MFace *mface, struct TFace *tface, unsigned int totface, unsigned int totvert, int selected, float *limit)
{
	UvVertMap *vmap;
	UvMapVert *buf;
	MFace *mf;
	TFace *tf;
	unsigned int a;
	int	i, totuv, nverts;

	totuv = 0;

	/* generate UvMapVert array */
	mf= mface;
	tf= tface;
	for(a=0; a<totface; a++, mf++, tf++)
		if(!selected || (!(tf->flag & TF_HIDE) && (tf->flag & TF_SELECT)))
			totuv += (mf->v4)? 4: 3;
		
	if(totuv==0)
		return NULL;
	
	vmap= (UvVertMap*)MEM_mallocN(sizeof(*vmap), "UvVertMap");
	if (!vmap)
		return NULL;

	vmap->vert= (UvMapVert**)MEM_callocN(sizeof(*vmap->vert)*totvert, "UvMapVert*");
	buf= vmap->buf= (UvMapVert*)MEM_mallocN(sizeof(*vmap->buf)*totuv, "UvMapVert");

	if (!vmap->vert || !vmap->buf) {
		free_uv_vert_map(vmap);
		return NULL;
	}

	mf= mface;
	tf= tface;
	for(a=0; a<totface; a++, mf++, tf++) {
		if(!selected || (!(tf->flag & TF_HIDE) && (tf->flag & TF_SELECT))) {
			nverts= (mf->v4)? 4: 3;

			for(i=0; i<nverts; i++) {
				buf->tfindex= i;
				buf->f= a;
				buf->separate = 0;
				buf->next= vmap->vert[*(&mf->v1 + i)];
				vmap->vert[*(&mf->v1 + i)]= buf;
				buf++;
			}
		}
	}
	
	/* sort individual uvs for each vert */
	tf= tface;
	for(a=0; a<totvert; a++) {
		UvMapVert *newvlist= NULL, *vlist=vmap->vert[a];
		UvMapVert *iterv, *v, *lastv, *next;
		float *uv, *uv2, uvdiff[2];

		while(vlist) {
			v= vlist;
			vlist= vlist->next;
			v->next= newvlist;
			newvlist= v;

			uv= (tf+v->f)->uv[v->tfindex];
			lastv= NULL;
			iterv= vlist;

			while(iterv) {
				next= iterv->next;

				uv2= (tf+iterv->f)->uv[iterv->tfindex];
				Vec2Subf(uvdiff, uv2, uv);


				if(fabs(uv[0]-uv2[0]) < limit[0] && fabs(uv[1]-uv2[1]) < limit[1]) {
					if(lastv) lastv->next= next;
					else vlist= next;
					iterv->next= newvlist;
					newvlist= iterv;
				}
				else
					lastv=iterv;

				iterv= next;
			}

			newvlist->separate = 1;
		}

		vmap->vert[a]= newvlist;
	}
	
	return vmap;
}

UvMapVert *get_uv_map_vert(UvVertMap *vmap, unsigned int v)
{
	return vmap->vert[v];
}

void free_uv_vert_map(UvVertMap *vmap)
{
	if (vmap) {
		if (vmap->vert) MEM_freeN(vmap->vert);
		if (vmap->buf) MEM_freeN(vmap->buf);
		MEM_freeN(vmap);
	}
}