test2/source/blender/src/editsima.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 *****
 */

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

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

#ifndef WIN32
#include <unistd.h>
#else
#include <io.h>
#include "BLI_winstuff.h"
#endif   
#include "MEM_guardedalloc.h"

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

#include "IMB_imbuf_types.h"

#include "DNA_mesh_types.h"
#include "DNA_meshdata_types.h"
#include "DNA_scene_types.h"
#include "DNA_screen_types.h"
#include "DNA_userdef_types.h"
#include "DNA_space_types.h"
#include "DNA_image_types.h"
#include "DNA_object_types.h" // only for uvedit_selectionCB() (struct Object)

#include "BKE_global.h"
#include "BKE_mesh.h"
#include "BKE_displist.h"

#include "BIF_gl.h"
#include "BIF_interface.h"
#include "BIF_screen.h"
#include "BIF_drawimage.h"
#include "BIF_editview.h"
#include "BIF_space.h"
#include "BIF_editsima.h"
#include "BIF_toolbox.h"
#include "BIF_mywindow.h"

#include "BSE_drawipo.h"
#include "BSE_edit.h"
#include "BSE_trans_types.h"

#include "BDR_editobject.h"
#include "BDR_unwrapper.h"

#include "blendef.h"
#include "mydevice.h"

struct uvvertsort {
	unsigned int v;
	unsigned char tf_sel;
	char flag;
	TFace *tface;
};

static int compuvvert(const void *u1, const void *u2)
{
	const struct uvvertsort *v1=u1, *v2=u2;
	if (v1->v > v2->v) return 1;
	else if (v1->v < v2->v) return -1;
	return 0;
}

int is_uv_tface_editing_allowed_silent(void)
{
	Mesh *me;

	if(G.obedit) return 0;
	if(G.sima->mode!=SI_TEXTURE) return 0;
	if(!(G.f & G_FACESELECT)) return 0;  
	me= get_mesh(OBACT);
	if(me==0 || me->tface==0) return 0;
	
	return 1;
}

int is_uv_tface_editing_allowed(void)
{
	if(G.obedit) error("Unable to perform action in Edit Mode");

	return is_uv_tface_editing_allowed_silent();
}

static void setLinkedLimit(float *limit)
{
	if(G.sima->image && G.sima->image->ibuf && G.sima->image->ibuf->x > 0 &&
	   G.sima->image->ibuf->y > 0) {
		limit[0]= 0.5/(float)G.sima->image->ibuf->x;
		limit[1]= 0.5/(float)G.sima->image->ibuf->y;
	}
	else
		limit[0]= limit[1]= 0.5/256.0;
}


void clever_numbuts_sima(void)
{
	float ocent[2], cent[2]= {0.0, 0.0};
	int imx, imy;
	int i, nactive= 0;
	Mesh *me;
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);
	
	if (G.sima->image && G.sima->image->ibuf) {
		imx= G.sima->image->ibuf->x;
		imy= G.sima->image->ibuf->y;
	} else
		imx= imy= 256;
	
	for (i=0; i<me->totface; i++) {
		MFace *mf= &((MFace*) me->mface)[i];
		TFace *tf= &((TFace*) me->tface)[i];
		
		if (!mf->v3 || !(tf->flag & TF_SELECT))
			continue;
		
		if (tf->flag & TF_SEL1) {
			cent[0]+= tf->uv[0][0];
			cent[1]+= tf->uv[0][1];
			nactive++;
		}
		if (tf->flag & TF_SEL2) {
			cent[0]+= tf->uv[1][0];
			cent[1]+= tf->uv[1][1];
			nactive++;
		}
		if (tf->flag & TF_SEL3) {
			cent[0]+= tf->uv[2][0];
			cent[1]+= tf->uv[2][1];
			nactive++;
		}
		if (mf->v4 && (tf->flag & TF_SEL4)) {
			cent[0]+= tf->uv[3][0];
			cent[1]+= tf->uv[3][1];
			nactive++;
		}
	}
	
	if (nactive) {
		cent[0]= (cent[0]*imx)/nactive;
		cent[1]= (cent[1]*imy)/nactive;

		add_numbut(0, NUM|FLO, "LocX:", -imx*20, imx*20, &cent[0], NULL);
		add_numbut(1, NUM|FLO, "LocY:", -imy*20, imy*20, &cent[1], NULL);
		
		ocent[0]= cent[0];
		ocent[1]= cent[1];
		if (do_clever_numbuts((nactive==1)?"Active Vertex":"Selected Center", 2, REDRAW)) {
			float delta[2];
			
			delta[0]= (cent[0]-ocent[0])/imx;
			delta[1]= (cent[1]-ocent[1])/imy;

			for (i=0; i<me->totface; i++) {
				MFace *mf= &((MFace*) me->mface)[i];
				TFace *tf= &((TFace*) me->tface)[i];
			
				if (!mf->v3 || !(tf->flag & TF_SELECT))
					continue;
			
				if (tf->flag & TF_SEL1) {
					tf->uv[0][0]+= delta[0];
					tf->uv[0][1]+= delta[1];
				}
				if (tf->flag & TF_SEL2) {
					tf->uv[1][0]+= delta[0];
					tf->uv[1][1]+= delta[1];
				}
				if (tf->flag & TF_SEL3) {
					tf->uv[2][0]+= delta[0];
					tf->uv[2][1]+= delta[1];
				}
				if (mf->v4 && (tf->flag & TF_SEL4)) {
					tf->uv[3][0]+= delta[0];
					tf->uv[3][1]+= delta[1];
				}
			}
			
			allqueue(REDRAWVIEW3D, 0);
		}
	}
}

static void sima_pixelgrid(float *loc, float sx, float sy)
{
	float y;
	float x;
	
	if(G.sima->flag & SI_NOPIXELSNAP) {
		loc[0]= sx;
		loc[1]= sy;
	}
	else {
		if(G.sima->image && G.sima->image->ibuf) {
			x= G.sima->image->ibuf->x;
			y= G.sima->image->ibuf->y;
		
			sx= floor(x*sx)/x;
			if(G.sima->flag & SI_CLIP_UV) {
				CLAMP(sx, 0, 1.0);
			}
			loc[0]= sx;
			
			sy= floor(y*sy)/y;
			if(G.sima->flag & SI_CLIP_UV) {
				CLAMP(sy, 0, 1.0);
			}
			loc[1]= sy;
		}
		else {
			loc[0]= sx;
			loc[1]= sy;
		}
	}
}


static void be_square_tface_uv(Mesh *me)
{
	TFace *tface;
	MFace *mface;
	int a;
	
	/* if 1 vertex selected: doit (with the selected vertex) */
	for(a=me->totface, mface= me->mface, tface= me->tface; a>0; a--, tface++, mface++) {
		if(mface->v4) {
			if(tface->flag & TF_SELECT) {
				if(tface->flag & TF_SEL1) {
					if( tface->uv[1][0] == tface->uv[2][0] ) {
						tface->uv[1][1]= tface->uv[0][1];
						tface->uv[3][0]= tface->uv[0][0];
					}
					else {	
						tface->uv[1][0]= tface->uv[0][0];
						tface->uv[3][1]= tface->uv[0][1];
					}
					
				}
				if(tface->flag & TF_SEL2) {
					if( tface->uv[2][1] == tface->uv[3][1] ) {
						tface->uv[2][0]= tface->uv[1][0];
						tface->uv[0][1]= tface->uv[1][1];
					}
					else {
						tface->uv[2][1]= tface->uv[1][1];
						tface->uv[0][0]= tface->uv[1][0];
					}

				}
				if(tface->flag & TF_SEL3) {
					if( tface->uv[3][0] == tface->uv[0][0] ) {
						tface->uv[3][1]= tface->uv[2][1];
						tface->uv[1][0]= tface->uv[2][0];
					}
					else {
						tface->uv[3][0]= tface->uv[2][0];
						tface->uv[1][1]= tface->uv[2][1];
					}
				}
				if(tface->flag & TF_SEL4) {
					if( tface->uv[0][1] == tface->uv[1][1] ) {
						tface->uv[0][0]= tface->uv[3][0];
						tface->uv[2][1]= tface->uv[3][1];
					}
					else  {
						tface->uv[0][1]= tface->uv[3][1];
						tface->uv[2][0]= tface->uv[3][0];
					}

				}
			}
		}
	}

}

void tface_do_clip(void)
{
	Mesh *me;
	TFace *tface;
	int a, b;
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);
	tface= me->tface;
	
	for(a=0; a<me->totface; a++, tface++) {
		if(tface->flag & TF_SELECT) {
			for(b=0; b<4; b++) {
				CLAMP(tface->uv[b][0], 0.0, 1.0);
				CLAMP(tface->uv[b][1], 0.0, 1.0);
			}
		}
	}
	
}

void transform_tface_uv(int mode)
{
	MFace *mface;
	TFace *tface;
	Mesh *me;
	TransVert *transmain, *tv;

 	float dist, xdist, ydist, aspx, aspy;
	float asp, dx1, dx2, dy1, dy2, phi, dphi, co, si;
	float size[2], sizefac;
	float dx, dy, dvec2[2], dvec[2], div, cent[2];
	float x, y, min[2], max[2], vec[2], xtra[2], ivec[2];
	int xim, yim, tot=0, a, b, firsttime=1, afbreek=0, align= 0;
	int propmode= 0, proptot= 0, midtog= 0, proj= 0, prop_recalc= 1;
	unsigned short event = 0;
	short mval[2], val, xo, yo, xn, yn, xc, yc;
	char str[80];
 	extern float prop_size, prop_cent[3]; 
 	extern int prop_mode;
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);
	
 	if(G.f & G_PROPORTIONAL) propmode= 1;
  	
	min[0]= min[1]= 10000.0;
	max[0]= max[1]= -10000.0;
	
	calc_image_view(G.sima, 'f');
	
	if(G.sima->image && G.sima->image->ibuf) {
		xim= G.sima->image->ibuf->x;
		yim= G.sima->image->ibuf->y;
	}
	else {
		xim= yim= 256;
	}
	aspx = (float)xim/256.0;
	aspy = (float)yim/256.0;

	/* which vertices are involved? */
	tface= me->tface;
	mface= me->mface;
	for(a=me->totface; a>0; a--, tface++, mface++) {
		if(mface->v3 && tface->flag & TF_SELECT) {
			if(tface->flag & TF_SEL1) tot++;
			if(tface->flag & TF_SEL2) tot++;
			if(tface->flag & TF_SEL3) tot++;
			if(mface->v4 && (tface->flag & TF_SEL4)) tot++;
			if(propmode) {
				if(mface->v4) proptot+=4;
				else proptot+=3;
			}
		}
	}
	if(tot==0) return;
	if(propmode) tot= proptot;

	G.moving= 1;
	prop_size/= 3;
	
	tv=transmain= MEM_callocN(tot*sizeof(TransVert), "transmain");

	tface= me->tface;
	mface= me->mface;
	for(a=me->totface; a>0; a--, tface++, mface++) {
		if(mface->v3 && tface->flag & TF_SELECT) {
			if (tface->flag & TF_SEL1 || propmode) {
				tv->loc= tface->uv[0];
				if(tface->flag & TF_SEL1) tv->flag= 1;
				tv++;
			}
			if (tface->flag & TF_SEL2 || propmode) {
				tv->loc= tface->uv[1];
				if(tface->flag & TF_SEL2) tv->flag= 1;
				tv++;
			}
			if (tface->flag & TF_SEL3 || propmode) {
				tv->loc= tface->uv[2];
				if(tface->flag & TF_SEL3) tv->flag= 1;
				tv++;
			}
			if(mface->v4) {
				if (tface->flag & TF_SEL4 || propmode) {
					tv->loc= tface->uv[3];
					if(tface->flag & TF_SEL4) tv->flag= 1;
					tv++;
				}
			}
		}
	}
	
	a= tot;
	tv= transmain;
	while(a--) {
		tv->oldloc[0]= tv->loc[0];
		tv->oldloc[1]= tv->loc[1];
		if(tv->flag) {
			DO_MINMAX2(tv->loc, min, max);
		}
		tv++;
	}

	cent[0]= (min[0]+max[0])/2.0;
	cent[1]= (min[1]+max[1])/2.0;
	prop_cent[0]= cent[0];
	prop_cent[1]= cent[1];

	ipoco_to_areaco_noclip(G.v2d, cent, mval);
	xc= mval[0];
	yc= mval[1];
	
	getmouseco_areawin(mval);
	xo= xn= mval[0];
	yo= yn= mval[1];
	dvec[0]= dvec[1]= 0.0;
	dx1= xc-xn; 
	dy1= yc-yn;
	phi= 0.0;
	
	
	sizefac= sqrt( (float)((yc-yn)*(yc-yn)+(xn-xc)*(xn-xc)) );
	if(sizefac<2.0) sizefac= 2.0;

	while(afbreek==0) {
		getmouseco_areawin(mval);
		if(((mval[0]!=xo || mval[1]!=yo) && !(mode=='w')) || firsttime) {
			if(propmode && prop_recalc && transmain) {
				a= tot;
				tv= transmain;

				while(a--) {
					if(tv->oldloc[0]<min[0]) xdist= tv->oldloc[0]-min[0];
					else if(tv->oldloc[0]>max[0]) xdist= tv->oldloc[0]-max[0];
					else xdist= 0.0;
					xdist*= aspx;

					if(tv->oldloc[1]<min[1]) ydist= tv->oldloc[1]-min[1];
					else if(tv->oldloc[1]>max[1]) ydist= tv->oldloc[1]-max[1];
					else ydist= 0.0;
					ydist*= aspy;

					dist= sqrt(xdist*xdist + ydist*ydist);
					if(dist==0.0) tv->fac= 1.0;
					else if(dist > prop_size) tv->fac= 0.0;
					else {
						dist= (prop_size-dist)/prop_size;
						if(prop_mode==1)
							tv->fac= 3.0*dist*dist - 2.0*dist*dist*dist;
						else tv->fac= dist*dist;
					}
					tv++;
				}
				prop_recalc= 0;
			}
			if(mode=='g') {
			
				dx= mval[0]- xo;
				dy= mval[1]- yo;
	
				div= G.v2d->mask.xmax-G.v2d->mask.xmin;
				dvec[0]+= (G.v2d->cur.xmax-G.v2d->cur.xmin)*(dx)/div;
	
				div= G.v2d->mask.ymax-G.v2d->mask.ymin;
				dvec[1]+= (G.v2d->cur.ymax-G.v2d->cur.ymin)*(dy)/div;
				
				if(midtog) dvec[proj]= 0.0;
				
				dvec2[0]= dvec[0];
				dvec2[1]= dvec[1];
				apply_keyb_grid(dvec2, 0.0, 1.0/8.0, 1.0/16.0, U.flag & USER_AUTOGRABGRID);
				apply_keyb_grid(dvec2+1, 0.0, 1.0/8.0, 1.0/16.0, U.flag & USER_AUTOGRABGRID);

				vec[0]= dvec2[0];
				vec[1]= dvec2[1];
				
				if(G.sima->flag & SI_CLIP_UV) {
					if(vec[0]< -min[0]) vec[0]= -min[0];
					if(vec[1]< -min[1]) vec[1]= -min[1];
					if(vec[0]> 1.0-max[0]) vec[0]= 1.0-max[0];
					if(vec[1]> 1.0-max[1]) vec[1]= 1.0-max[1];
				}
				tv= transmain;
				if (propmode) {
					for(a=0; a<tot; a++, tv++) {
						x= tv->oldloc[0]+tv->fac*vec[0];
						y= tv->oldloc[1]+tv->fac*vec[1];
						
						sima_pixelgrid(tv->loc, x, y);
					}
				} else {
					for(a=0; a<tot; a++, tv++) {
						x= tv->oldloc[0]+vec[0];
						y= tv->oldloc[1]+vec[1];
						
						sima_pixelgrid(tv->loc, x, y);
					}
				}
					
				ivec[0]= (vec[0]*xim);
				ivec[1]= (vec[1]*yim);

				if(G.sima->flag & SI_BE_SQUARE) be_square_tface_uv(me);
			
				sprintf(str, "X: %.4f   Y: %.4f  ", ivec[0], ivec[1]);
				headerprint(str);
			}
			else if(mode=='r') {

				dx2= xc-mval[0];
				dy2= yc-mval[1];
				
				div= sqrt( (dx1*dx1+dy1*dy1)*(dx2*dx2+dy2*dy2));
				if(div>1.0) {
				
					dphi= (dx1*dx2+dy1*dy2)/div;
					dphi= saacos(dphi);
					if( (dx1*dy2-dx2*dy1)<0.0 ) dphi= -dphi;
					
					if(G.qual & LR_SHIFTKEY) phi+= dphi/30.0;
					else phi+= dphi;

					apply_keyb_grid(&phi, 0.0, (5.0/180)*M_PI, (1.0/180)*M_PI, U.flag & USER_AUTOROTGRID);
					
					dx1= dx2; 
					dy1= dy2;
					
					co= cos(phi);
					si= sin(phi);
					asp= (float)yim/(float)xim;

					tv= transmain;
					for(a=0; a<tot; a++, tv++) {
						if(propmode) {
							co= cos(phi*tv->fac);
							si= sin(phi*tv->fac);
						}
						x= ( co*( tv->oldloc[0]-cent[0]) - si*asp*(tv->oldloc[1]-cent[1]) ) +cent[0];
						y= ( si*( tv->oldloc[0]-cent[0])/asp + co*(tv->oldloc[1]-cent[1]) ) +cent[1];
						sima_pixelgrid(tv->loc, x, y);
						
						if(G.sima->flag & SI_CLIP_UV) {
							if(tv->loc[0]<0.0) tv->loc[0]= 0.0;
							else if(tv->loc[0]>1.0) tv->loc[0]= 1.0;
							if(tv->loc[1]<0.0) tv->loc[1]= 0.0;
							else if(tv->loc[1]>1.0) tv->loc[1]= 1.0;
						}
					}					
					
					sprintf(str, "Rot: %.3f  ", phi*180.0/M_PI);
					headerprint(str);
				}
			}
			else if(mode=='s') {
				size[0]= size[1]= (sqrt((float)((yc-mval[1])*(yc-mval[1])+(mval[0]-xc)*(mval[0]-xc))))/sizefac;
				if(midtog) size[proj]= 1.0;
				
				apply_keyb_grid(size, 0.0, 0.1, 0.01, U.flag & USER_AUTOSIZEGRID);
				apply_keyb_grid(size+1, 0.0, 0.1, 0.01, U.flag & USER_AUTOSIZEGRID);

				xtra[0]= xtra[1]= 0;

				if(G.sima->flag & SI_CLIP_UV) {
					/* boundbox limit: four step plan: XTRA X */
	
					a=b= 0;
					if(size[0]*(min[0]-cent[0]) + cent[0] + xtra[0] < 0) 
						a= -size[0]*(min[0]-cent[0]) - cent[0];
					if(size[0]*(max[0]-cent[0]) + cent[0] + xtra[0] > 1.0) 
						b= 1.0 - size[0]*(max[0]-cent[0]) - cent[0];
					xtra[0]= (a+b)/2;
					
					/* SIZE X */
					if(size[0]*(min[0]-cent[0]) + cent[0] + xtra[0] < 0) 
						size[0]= (-cent[0]-xtra[0])/(min[0]-cent[0]);
					if(size[0]*(max[0]-cent[0]) + cent[0] +xtra[0] > 1.0) 
						size[0]= (1.0-cent[0]-xtra[0])/(max[0]-cent[0]);
						
					/* XTRA Y */
					a=b= 0;
					if(size[1]*(min[1]-cent[1]) + cent[1] + xtra[1] < 0) 
						a= -size[1]*(min[1]-cent[1]) - cent[1];
					if(size[1]*(max[1]-cent[1]) + cent[1] + xtra[1] > 1.0) 
						b= 1.0 - size[1]*(max[1]-cent[1]) - cent[1];
					xtra[1]= (a+b)/2;
					
					/* SIZE Y */
					if(size[1]*(min[1]-cent[1]) + cent[1] +xtra[1] < 0) 
						size[1]= (-cent[1]-xtra[1])/(min[1]-cent[1]);
					if(size[1]*(max[1]-cent[1]) + cent[1] + xtra[1]> 1.0) 
						size[1]= (1.0-cent[1]-xtra[1])/(max[1]-cent[1]);
				}

				/* if(midtog==0) { */
				/* 	if(size[1]>size[0]) size[1]= size[0]; */
				/* 	else if(size[0]>size[1]) size[0]= size[1]; */
				/* } */

				tv= transmain;
				if (propmode) {
					for(a=0; a<tot; a++, tv++) {
					
						x= (tv->fac*size[0] + 1.00-tv->fac)*(tv->oldloc[0]-cent[0])+ cent[0] + xtra[0];
						y= (tv->fac*size[1] + 1.00-tv->fac)*(tv->oldloc[1]-cent[1])+ cent[1] + xtra[1];
						sima_pixelgrid(tv->loc, x, y);
					}

				} else {
					for(a=0; a<tot; a++, tv++) {
					
						x= size[0]*(tv->oldloc[0]-cent[0])+ cent[0] + xtra[0];
						y= size[1]*(tv->oldloc[1]-cent[1])+ cent[1] + xtra[1];
						sima_pixelgrid(tv->loc, x, y);
					}
				}
				
				sprintf(str, "sizeX: %.3f   sizeY: %.3f", size[0], size[1]);
				headerprint(str);
			}
			else if(mode=='w') { /* weld / align */
				tv= transmain;
				for(a=0; a<tot; a++, tv++) {
					x= tv->oldloc[0];
					y= tv->oldloc[1];
					if(align==0) {
						x= cent[0];
						y= cent[1];
					}
					else if(align==1) y= cent[1];
					else if(align==2) x= cent[0];
					
					tv->loc[0]= x;
					tv->loc[1]= y;
					
					if(G.sima->flag & SI_CLIP_UV) {
						if(tv->loc[0]<0.0) tv->loc[0]= 0.0;
						else if(tv->loc[0]>1.0) tv->loc[0]= 1.0;
						if(tv->loc[1]<0.0) tv->loc[1]= 0.0;
						else if(tv->loc[1]>1.0) tv->loc[1]= 1.0;
					}
				}		
				
				if(align==0)
					sprintf(str, "Weld (X: Align along X, Y: Align along Y)");
				else if(align==1)
					sprintf(str, "X Axis Align (W: Weld, Y: Align along Y)");
				else if(align==2)
					sprintf(str, "Y Axis Align (W: Weld, X: Align along X)");
				headerprint(str);
			}
			
			xo= mval[0];
			yo= mval[1];
			
			if(G.sima->lock || mode=='w') force_draw_plus(SPACE_VIEW3D);
			else force_draw();
			
			firsttime= 0;
			
		}
		else BIF_wait_for_statechange();
		
		while(qtest()) {
			event= extern_qread(&val);
			if(val) {
				switch(event) {
				case ESCKEY:
				case RIGHTMOUSE:
				case LEFTMOUSE:
				case SPACEKEY:
				case RETKEY:
					afbreek= 1;
					break;
				case MIDDLEMOUSE:
					midtog= ~midtog;
					if(midtog) {
						if( abs(mval[0]-xn) > abs(mval[1]-yn)) proj= 1;
						else proj= 0;
						firsttime= 1;
					}
					break;
				case WHEELDOWNMOUSE:
				case PADPLUSKEY:
					if(propmode) {
						prop_size*= 1.1;
						prop_recalc= 1;
						firsttime= 1;
					}
					break;
				case WHEELUPMOUSE:
				case PADMINUS:
					if(propmode) {
						prop_size*= 0.90909090;
						prop_recalc= 1;
						firsttime= 1;
					}
					break;
				case WKEY:
				case XKEY:
				case YKEY:
					if(mode=='w') {
						if(event==WKEY) align= 0;
						else if(event==XKEY) align= 1;
						else align= 2;
					}
					else {
						if(midtog) {
							if(event==XKEY) {
								if(proj==1) midtog= ~midtog;
								else if(proj==0) proj= 1;
							}
							else if(event==YKEY) {
								if(proj==0) midtog= ~midtog;
								else if(proj==1) proj= 0;
							}
						}
						else {
							if(event==XKEY) {
								midtog= ~midtog;
								proj= 1;
							}
							else if(event==YKEY) {
								midtog= ~midtog;
								proj= 0;
							}
						}
					}
					firsttime= 1;
					break;
				default:
					arrows_move_cursor(event);
				}
			}

			if(afbreek) break;
		}
	}
	
	if(event==ESCKEY || event == RIGHTMOUSE) {
		tv= transmain;
		for(a=0; a<tot; a++, tv++) {
			tv->loc[0]= tv->oldloc[0];
			tv->loc[1]= tv->oldloc[1];
		}
	}
	MEM_freeN(transmain);
	
	if(mode=='g') if(G.sima->flag & SI_BE_SQUARE) be_square_tface_uv(me);

	G.moving= 0;
	prop_size*= 3;
	
	makeDispList(OBACT);
	allqueue(REDRAWVIEW3D, 0);
	scrarea_queue_headredraw(curarea);
	scrarea_queue_winredraw(curarea);
}

static void mirror_tface_uv(char mirroraxis)
{
	MFace *mface;
	TFace *tface;
	Mesh *me;
	float min[2], max[2], cent[2];
	int a, axis;
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);
	
	min[0]= min[1]= 10000.0;
	max[0]= max[1]= -10000.0;
	
	tface= me->tface;
	mface= me->mface;
	for(a=me->totface; a>0; a--, tface++, mface++) {
		if(tface->flag & TF_SELECT) {
			if(tface->flag & TF_SEL1) { DO_MINMAX2(tface->uv[0], min, max); }
			if(tface->flag & TF_SEL2) { DO_MINMAX2(tface->uv[1], min, max); }
			if(tface->flag & TF_SEL3) { DO_MINMAX2(tface->uv[2], min, max); }
			if(mface->v4 && (tface->flag & TF_SEL4)) {
				DO_MINMAX2(tface->uv[3], min, max);
			}
		}
	}

	cent[0]= (min[0]+max[0])/2.0;
	cent[1]= (min[1]+max[1])/2.0;

	if(mirroraxis=='x') axis= 0;
	else axis= 1;

	tface= me->tface;
	mface= me->mface;
	for(a=me->totface; a>0; a--, tface++, mface++) {
		if(tface->flag & TF_SELECT) {
			if(tface->flag & TF_SEL1)
				tface->uv[0][axis]= 2*cent[axis] - tface->uv[0][axis];
			if(tface->flag & TF_SEL2)
				tface->uv[1][axis]= 2*cent[axis] - tface->uv[1][axis];
			if(tface->flag & TF_SEL3)
				tface->uv[2][axis]= 2*cent[axis] - tface->uv[2][axis];
			if(mface->v4 && (tface->flag & TF_SEL4))
				tface->uv[3][axis]= 2*cent[axis] - tface->uv[3][axis];
		}
	}

	allqueue(REDRAWVIEW3D, 0);
	allqueue(REDRAWIMAGE, 0);
}

void mirrormenu_tface_uv(void)
{
	short mode= 0;

	if( is_uv_tface_editing_allowed()==0 ) return;

	mode= pupmenu("Mirror%t|X Axis%x1|Y Axis%x2|");

	if(mode==-1) return;

	if(mode==1) mirror_tface_uv('x');
	else if(mode==2) mirror_tface_uv('y');
}


void select_swap_tface_uv(void)
{
	Mesh *me;
	TFace *tface;
	MFace *mface;
	int a, sel=0;
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);

	for(a=me->totface, tface= me->tface; a>0; a--, tface++) {
		if(tface->flag & TF_SELECT) {	
			if(tface->flag & (TF_SEL1+TF_SEL2+TF_SEL3+TF_SEL4)) {
				sel= 1;
				break;
			}
		}
	}
	
	mface= me->mface;
	for(a=me->totface, tface= me->tface; a>0; a--, tface++, mface++) {
		if(tface->flag & TF_SELECT) {
			if(mface->v4) {
				if(sel) tface->flag &= ~(TF_SEL1+TF_SEL2+TF_SEL3+TF_SEL4);
				else tface->flag |= (TF_SEL1+TF_SEL2+TF_SEL3+TF_SEL4);
			}
			else if(mface->v3) {
				if(sel) tface->flag &= ~(TF_SEL1+TF_SEL2+TF_SEL3+TF_SEL4);
				else tface->flag |= (TF_SEL1+TF_SEL2+TF_SEL3);
			}
		}
	}
	
	allqueue(REDRAWIMAGE, 0);
}

static int msel_hit(float *limit, unsigned int *hitarray, unsigned int vertexid, float **uv, float *uv2)
{
	int i;
	for(i=0; i< 4; i++) {
		if(hitarray[i] == vertexid) {
			if(G.sima->flag & SI_LOCALSTICKY) {
				if(fabs(uv[i][0]-uv2[0]) < limit[0] &&
			    fabs(uv[i][1]-uv2[1]) < limit[1])
					return 1;
			}
			else return 1;
		}
	}
	return 0;
}

void mouse_select_sima(void)
{
	Mesh *me;
	TFace *tface, *closesttface= NULL;
	MFace *mface, *closestmface= NULL;
	int a, redraw= 0, uvcent[2], selectsticky= 0, sticky, actface;
	int temp, dist= 0x7FFFFFF, fdist= 0x7FFFFFF, fdistmin= 0x7FFFFFF;
	short mval[2], uval[2], val= 0;
	char *flagpoin= 0;
	unsigned int hitvert[4]= {0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF};
	float *hituv[4], limit[2];
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);
	getmouseco_areawin(mval);	

	setLinkedLimit(limit);
	actface= (G.qual & LR_ALTKEY || G.sima->flag & SI_SELACTFACE);
	sticky= (G.qual & LR_CTRLKEY || G.sima->flag & SI_STICKYUVS ||
	         G.sima->flag & SI_LOCALSTICKY);

	/* go for one run through all faces. collect all information needed */
	mface= me->mface;
	tface= me->tface;
	for(a=me->totface; a>0; a--, tface++, mface++) {
		if(tface->flag & TF_SELECT && mface->v3) {
		
			uvco_to_areaco_noclip(tface->uv[0], uval);
			uvcent[0]= uval[0];
			uvcent[1]= uval[1];
			temp= abs(mval[0]-uval[0]) + abs(mval[1]-uval[1]);
			if(tface->flag & TF_SEL1) temp += 5;
			if(temp<dist) { 
				flagpoin= &tface->flag;
				dist= temp; 
				val= TF_SEL1;
				hitvert[1]= hitvert[2]= hitvert[3]= 0xFFFFFFFF;    
				hitvert[0]= mface->v1;
				hituv[0]= tface->uv[0];
			}
	
			uvco_to_areaco_noclip(tface->uv[1], uval);
			temp= abs(mval[0]-uval[0]) + abs(mval[1]-uval[1]);
			uvcent[0] += uval[0];
			uvcent[1] += uval[1];
			if(tface->flag & TF_SEL2) temp += 5;
			if(temp<dist) { 
				flagpoin= &tface->flag;
				dist= temp; 
				val= TF_SEL2;
				hitvert[0]= hitvert[2]= hitvert[3]= 0xFFFFFFFF;    
				hitvert[1]= mface->v2;
				hituv[1]= tface->uv[1];
			}
	
			uvco_to_areaco_noclip(tface->uv[2], uval);
			temp= abs(mval[0]-uval[0]) + abs(mval[1]-uval[1]);
			uvcent[0] += uval[0];
			uvcent[1] += uval[1];
			if(tface->flag & TF_SEL3) temp += 5;
			if(temp<dist) { 
				flagpoin= &tface->flag;
				dist= temp; 
				val= TF_SEL3;
				hitvert[0]= hitvert[1]= hitvert[3]= 0xFFFFFFFF;    
				hitvert[2]= mface->v3;
				hituv[2]= tface->uv[2];
			}
	
			if(mface->v4) {
				uvco_to_areaco_noclip(tface->uv[3], uval);
				uvcent[0] += uval[0];
				uvcent[1] += uval[1];
				temp= abs(mval[0]-uval[0]) + abs(mval[1]-uval[1]);
				if(tface->flag & TF_SEL4) temp += 5;
				if(temp<dist) { 
					flagpoin= &tface->flag;
					dist= temp; 
					val= TF_SEL4;
					hitvert[0]= hitvert[1]= hitvert[2]= 0xFFFFFFFF;    
					hitvert[3] = mface->v4;
					hituv[3]= tface->uv[3];
				}
				uvcent[0] /= 4;
				uvcent[1] /= 4;
			}
			else {
				uvcent[0] /= 3;
				uvcent[1] /= 3;
			}
			
			/* find face closest to mouse */			
			if(actface) {
				fdist= abs(mval[0]- uvcent[0])+ abs(mval[1]- uvcent[1]);
				if (fdist < fdistmin){
					closesttface= tface;
					closestmface= mface;
					fdistmin= fdist;
				}
			}
		}
	}
	
	if(!flagpoin)
		return;

	if(actface && closesttface) {
		closesttface->flag |= TF_ACTIVE;
		hitvert[0]= closestmface->v1;
		hituv[0]= closesttface->uv[0];
		hitvert[1]= closestmface->v2;
		hituv[1]= closesttface->uv[1];
		hitvert[2]= closestmface->v3;
		hituv[2]= closesttface->uv[2];
		if(closestmface->v4) {
			hitvert[3]= closestmface->v4;
			hituv[3]= closesttface->uv[3];
		}
	}

	if(G.qual & LR_SHIFTKEY) {
		/* (de)select face */
		if(actface) {
			if(!(~closesttface->flag & (TF_SEL1|TF_SEL2|TF_SEL3))
			   && (!closestmface->v4 || closesttface->flag & TF_SEL4)) {
				closesttface->flag &= ~(TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
				selectsticky= 0;
			}
			else {
				closesttface->flag |= TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4;
				selectsticky= 1;
			}
		}
		/* (de)select uv node */
		else {
			if(*flagpoin & val) {
				*flagpoin &= ~val;
				selectsticky= 0;
			}
			else {
				*flagpoin |= val;
				selectsticky= 1;
			}
		}

		/* (de)select sticky uv nodes */
		if(sticky || actface) {
			mface= me->mface;
			tface= me->tface;
			/* deselect */
			if(selectsticky==0) {
				for(a=me->totface; a>0; a--, tface++, mface++) {
					if(!(tface->flag & TF_SELECT && mface->v3)) continue;
					if(closesttface && tface!=closesttface)
						tface->flag &=~ TF_ACTIVE;
					if (!sticky) continue;

					if(msel_hit(limit,hitvert,mface->v1,hituv,tface->uv[0]))
						tface->flag &= ~TF_SEL1;
					if(msel_hit(limit,hitvert,mface->v2,hituv,tface->uv[1]))
						tface->flag &= ~TF_SEL2;
					if(msel_hit(limit,hitvert,mface->v3,hituv,tface->uv[2]))
						tface->flag &= ~TF_SEL3;
					if (mface->v4)
						if(msel_hit(limit,hitvert,mface->v4,hituv,tface->uv[3]))
							tface->flag &= ~TF_SEL4;
				}
			}
			/* select */
			else {
				for(a=me->totface; a>0; a--, tface++, mface++) {
					if(!(tface->flag & TF_SELECT && mface->v3)) continue;
					if(closesttface && tface!=closesttface)
						tface->flag &=~ TF_ACTIVE;
					if (!sticky) continue;

					if(msel_hit(limit,hitvert,mface->v1,hituv,tface->uv[0]))
						tface->flag |= TF_SEL1;
					if(msel_hit(limit,hitvert,mface->v2,hituv,tface->uv[1]))
						tface->flag |= TF_SEL2;
					if(msel_hit(limit,hitvert,mface->v3,hituv,tface->uv[2]))
						tface->flag |= TF_SEL3;
					if (mface->v4)
						if(msel_hit(limit,hitvert,mface->v4,hituv,tface->uv[3]))
							tface->flag |= TF_SEL4;
				}
			}
		}
	}
	else {
		/* select face and deselect other faces */ 
		if(actface) {
			mface= me->mface;
			tface= me->tface;
			for(a=me->totface; a>0; a--, tface++, mface++) {
				tface->flag &= ~(TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
				if(closesttface && tface!=closesttface)
					tface->flag &=~ TF_ACTIVE;
			}
			if(closesttface)
				closesttface->flag |= (TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
			redraw= 1;
		}

		/* deselect uvs, and select sticky uvs */
		mface= me->mface;
		tface= me->tface;
		for(a=me->totface; a>0; a--, tface++, mface++) {
			if(tface->flag & TF_SELECT && mface->v3) {
				if(!actface) tface->flag &= ~(TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
				if(!sticky) continue;

				if(msel_hit(limit,hitvert,mface->v1,hituv,tface->uv[0]))
					tface->flag |=TF_SEL1;
				if(msel_hit(limit,hitvert,mface->v2,hituv,tface->uv[1]))
					tface->flag |=TF_SEL2;
				if(msel_hit(limit,hitvert,mface->v3,hituv,tface->uv[2]))
					tface->flag |=TF_SEL3;
				if(mface->v4)
					if(msel_hit(limit,hitvert,mface->v4,hituv,tface->uv[3]))
						tface->flag |=TF_SEL4;
			}
		}
		
		if(!actface) 
			*flagpoin |= val;
	}
	
	force_draw();
	
	std_rmouse_transform(transform_tface_uv);
}

void borderselect_sima(void)
{
	Mesh *me;
	TFace *tface;
	MFace *mface;
	rcti rect;
	rctf rectf;
	int a, val;
	short mval[2];

	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);

	val= get_border(&rect, 3);

	if(val) {
		mval[0]= rect.xmin;
		mval[1]= rect.ymin;
		areamouseco_to_ipoco(G.v2d, mval, &rectf.xmin, &rectf.ymin);
		mval[0]= rect.xmax;
		mval[1]= rect.ymax;
		areamouseco_to_ipoco(G.v2d, mval, &rectf.xmax, &rectf.ymax);

		mface= me->mface;
		for(a=me->totface, tface= me->tface; a>0; a--, tface++, mface++) {
		
			if(tface->flag & TF_SELECT) {
				
				if(BLI_in_rctf(&rectf, (float)tface->uv[0][0], (float)tface->uv[0][1])) {
					if(val==LEFTMOUSE) tface->flag |= TF_SEL1;
					else tface->flag &= ~TF_SEL1;
				}
				if(BLI_in_rctf(&rectf, (float)tface->uv[1][0], (float)tface->uv[1][1])) {
					if(val==LEFTMOUSE) tface->flag |= TF_SEL2;
					else tface->flag &= ~TF_SEL2;
				}
				if(BLI_in_rctf(&rectf, (float)tface->uv[2][0], (float)tface->uv[2][1])) {
					if(val==LEFTMOUSE) tface->flag |= TF_SEL3;
					else tface->flag &= ~TF_SEL3;
				}
				if(mface->v4 && BLI_in_rctf(&rectf, (float)tface->uv[3][0], (float)tface->uv[3][1])) {
					if(val==LEFTMOUSE) tface->flag |= TF_SEL4;
					else tface->flag &= ~TF_SEL4;
				}
			}
							
		}
		scrarea_queue_winredraw(curarea);
	}
}

/** This is an ugly function to set the Tface selection flags depending
  * on whether its UV coordinates are inside the normalized 
  * area with radius rad and offset offset. These coordinates must be
  * normalized to 1.0 
  * Just for readability...
  */

void sel_uvco_inside_radius(short sel, TFace *tface, int index, float *offset, float *ell, short select_mask)
{
	// normalized ellipse: ell[0] = scaleX,
	//                        [1] = scaleY

	float *uv = tface->uv[index];
	float x, y, r2;

	x = (uv[0] - offset[0]) * ell[0];
	y = (uv[1] - offset[1]) * ell[1];

	r2 = x * x + y * y;
	if (r2 < 1.0) {
		if (sel == LEFTMOUSE) tface->flag |= select_mask;
		else tface->flag &= ~select_mask;
	}
}

// see below:
/** gets image dimensions of the 2D view 'v' */
static void getSpaceImageDimension(SpaceImage *sima, float *xy)
{
	Image *img = sima->image;
	float z;

	z = sima->zoom;

	if (img) {
		xy[0] = img->ibuf->x * z;
		xy[1] = img->ibuf->y * z;
	} else {
		xy[0] = 256 * z;
		xy[1] = 256 * z;
	}
}

/** Callback function called by circle_selectCB to enable 
  * brush select in UV editor.
  */

void uvedit_selectionCB(short selecting, Object *editobj, short *mval, float rad) 
{
	float offset[2];
	Mesh *me;
	MFace *mface;
	TFace *tface;
	int i;

	float ellipse[2]; // we need to deal with ellipses, as
	                  // non square textures require for circle
					  // selection. this ellipse is normalized; r = 1.0
	
	me = get_mesh(editobj);

	getSpaceImageDimension(curarea->spacedata.first, ellipse);
	ellipse[0] /= rad;
	ellipse[1] /= rad;

	areamouseco_to_ipoco(G.v2d, mval, &offset[0], &offset[1]);

	mface= me->mface;
	tface= me->tface;

	if (selecting) {
		for(i = 0; i < me->totface; i++) {
			sel_uvco_inside_radius(selecting, tface, 0, offset, ellipse, TF_SEL1);
			sel_uvco_inside_radius(selecting, tface, 1, offset, ellipse, TF_SEL2);
			sel_uvco_inside_radius(selecting, tface, 2, offset, ellipse, TF_SEL3);
			if (mface->v4)
				sel_uvco_inside_radius(selecting, tface, 3, offset, ellipse, TF_SEL4);
			
			tface++; mface++;

		}

		if(G.f & G_DRAWFACES) { /* full redraw only if necessary */
			draw_sel_circle(0, 0, 0, 0, 0); /* signal */
			force_draw();
		}
		else { /* force_draw() is no good here... */
			glDrawBuffer(GL_FRONT);
			draw_tfaces();
			glDrawBuffer(GL_BACK);
		}
	}	
}


void mouseco_to_curtile(void)
{
	float fx, fy;
	short mval[2];
	
	if( is_uv_tface_editing_allowed()==0) return;

	if(G.sima->image && G.sima->image->tpageflag & IMA_TILES) {
		
		G.sima->flag |= SI_EDITTILE;
		
		while(get_mbut()&L_MOUSE) {
			
			calc_image_view(G.sima, 'f');
			
			getmouseco_areawin(mval);
			areamouseco_to_ipoco(G.v2d, mval, &fx, &fy);

			if(fx>=0.0 && fy>=0.0 && fx<1.0 && fy<1.0) {
			
				fx= (fx)*G.sima->image->xrep;
				fy= (fy)*G.sima->image->yrep;
				
				mval[0]= fx;
				mval[1]= fy;
				
				G.sima->curtile= mval[1]*G.sima->image->xrep + mval[0];
			}

			scrarea_do_windraw(curarea);
			screen_swapbuffers();
		
		}
		
		G.sima->flag &= ~SI_EDITTILE;

		image_changed(G.sima, 1);

		allqueue(REDRAWVIEW3D, 0);
		scrarea_queue_winredraw(curarea);
	}
}

void hide_tface_uv(int swap)
{
	Mesh *me;
	TFace *tface;
	MFace *mface;
	int a;

	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);

	if(swap) {
		mface= me->mface;
		for(a=me->totface, tface= me->tface; a>0; a--, tface++, mface++) {
			if(mface->v3 && tface->flag & TF_SELECT) {
				if((tface->flag & (TF_SEL1|TF_SEL2|TF_SEL3))==0) {
					if(!mface->v4)
						tface->flag &= ~TF_SELECT;
					else if(!(tface->flag & TF_SEL4))
						tface->flag &= ~TF_SELECT;
				}
			}
		}
	} else {
		mface= me->mface;
		for(a=me->totface, tface= me->tface; a>0; a--, tface++, mface++) {
			if(mface->v3 && tface->flag & TF_SELECT) {
				if(tface->flag & (TF_SEL1|TF_SEL2|TF_SEL3))
						tface->flag &= ~TF_SELECT;
				else if(mface->v4 && tface->flag & TF_SEL4)
						tface->flag &= ~TF_SELECT;
			}
		}
	}
	allqueue(REDRAWVIEW3D, 0);
	allqueue(REDRAWIMAGE, 0);
}

void reveal_tface_uv(void)
{
	Mesh *me;
	TFace *tface;
	MFace *mface;
	int a;

	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);

	mface= me->mface;
	for(a=me->totface, tface= me->tface; a>0; a--, tface++, mface++)
		if(mface->v3 && !(tface->flag & TF_HIDE))
			if(!(tface->flag & TF_SELECT))
				tface->flag |= (TF_SELECT|TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
	
	allqueue(REDRAWVIEW3D, 0);
	allqueue(REDRAWIMAGE, 0);
}

void stitch_uv_tface(int mode)
{
	MFace *mface;
	TFace *tface;
	Mesh *me;
	unsigned int a, b, c, vtot, vtot2, tot;
	float newuv[2], limit[2], *uv, *uv1;
	struct uvvertsort *sortblock, *sb, *sb1, *sb2;
	
	if( is_uv_tface_editing_allowed()==0 ) return;

	limit[0]= limit[1]= 20.0;
	if(mode==1) {
		add_numbut(0, NUM|FLO, "Limit:", 0.1, 1000.0, &limit[0], NULL);
		if (!do_clever_numbuts("Stitch UVs", 1, REDRAW))
			return;
	}

	if(G.sima->image && G.sima->image->ibuf && G.sima->image->ibuf->x > 0 &&
	   G.sima->image->ibuf->y > 0) {
		limit[1]= limit[0]/(float)G.sima->image->ibuf->y;
		limit[0]= limit[0]/(float)G.sima->image->ibuf->x;
	}
	else
		limit[0]= limit[1]= limit[0]/256.0;
	
	me= get_mesh(OBACT);
	
	tot= 0;
	mface= me->mface;
	for(a=me->totface, tface=me->tface; a>0; a--, tface++, mface++) {
		if((tface->flag & TF_SELECT) && mface->v3) {
			if(tface->flag & TF_SEL1) tot++;
			if(tface->flag & TF_SEL2) tot++;
			if(tface->flag & TF_SEL3) tot++;
			if(mface->v4 && tface->flag & TF_SEL4) tot++; 
		}
	}
	if(tot==0) return;

	sb= sortblock= MEM_callocN(sizeof(struct uvvertsort)*tot,"sortstitchuv");

	mface= me->mface;
	for(a=me->totface, tface=me->tface; a>0; a--, tface++, mface++) {
		if((tface->flag & TF_SELECT) && mface->v3) {
			if(tface->flag & TF_SEL1) {
				sb->v= mface->v1;
				sb->tface= tface;
				sb->tf_sel= 0;
				sb++;
			}
			if(tface->flag & TF_SEL2) {
				sb->v= mface->v2;
				sb->tface= tface;
				sb->tf_sel= 1;
				sb++;
			}
			if(tface->flag & TF_SEL3) {
				sb->v= mface->v3;
				sb->tface= tface;
				sb->tf_sel= 2;
				sb++;
			}
			if(mface->v4 && tface->flag & TF_SEL4) {
				sb->v= mface->v4;
				sb->tface = tface;
				sb->tf_sel= 3;
				sb++;
			}
		}
	}
	
	/* sort by vertex */
	qsort(sortblock, tot, sizeof(struct uvvertsort), compuvvert);

	if(mode==0) {
		for (a=0, sb=sortblock; a<tot; a+=vtot, sb+=vtot) {
			newuv[0]= 0; newuv[1]= 0;
			vtot= 0;

			for (b=a, sb1=sb; b<tot && sb1->v==sb->v; b++, sb1++) {
				newuv[0] += sb1->tface->uv[sb1->tf_sel][0];
				newuv[1] += sb1->tface->uv[sb1->tf_sel][1];
				vtot++;
			}

			newuv[0] /= vtot; newuv[1] /= vtot;

			for (b=a, sb1=sb; b<a+vtot; b++, sb1++) {
				sb1->tface->uv[sb1->tf_sel][0]= newuv[0];
				sb1->tface->uv[sb1->tf_sel][1]= newuv[1];
			}
		}
	} else if(mode==1) {
		for (a=0, sb=sortblock; a<tot; a+=vtot, sb+=vtot) {
			vtot= 0;
			for (b=a, sb1=sb; b<tot && sb1->v==sb->v; b++, sb1++)
				vtot++;

			for (b=a, sb1=sb; b<a+vtot; b++, sb1++) {
				if(sb1->flag & 2) continue;

				newuv[0]= 0; newuv[1]= 0;
				vtot2 = 0;

				for (c=b, sb2=sb1; c<a+vtot; c++, sb2++) {
					uv = sb2->tface->uv[sb2->tf_sel];
					uv1 = sb1->tface->uv[sb1->tf_sel];
					if (fabs(uv[0]-uv1[0]) < limit[0] &&
					    fabs(uv[1]-uv1[1]) < limit[1]) {
						newuv[0] += uv[0];
						newuv[1] += uv[1];
						sb2->flag |= 2;
						sb2->flag |= 4;
						vtot2++;
					}
				}

				newuv[0] /= vtot2; newuv[1] /= vtot2;

				for (c=b, sb2=sb1; c<a+vtot; c++, sb2++) {
					if(sb2->flag & 4) {
						sb2->tface->uv[sb2->tf_sel][0]= newuv[0];
						sb2->tface->uv[sb2->tf_sel][1]= newuv[1];
						sb2->flag &= ~4;
					}
				}
			}
		}
	}
	MEM_freeN(sortblock);

	if(G.sima->flag & SI_BE_SQUARE) be_square_tface_uv(me);
	if(G.sima->flag & SI_CLIP_UV) tface_do_clip();

	allqueue(REDRAWVIEW3D, 0);
	scrarea_queue_winredraw(curarea);
}

void select_linked_tface_uv(void)
{
	MFace *mface;
	TFace *tface;
	Mesh *me;
	char sel;
	unsigned int a, b, c, vtot, tot;
	float limit[2], *uv, *uv1;
	struct uvvertsort *sortblock, *sb, *sb1, *sb2;
	
	if( is_uv_tface_editing_allowed()==0 ) return;

	me= get_mesh(OBACT);
	
	setLinkedLimit(limit);

	tot= 0;
	mface= me->mface;
	for(a=me->totface, tface=me->tface; a>0; a--, tface++, mface++) {
		if((tface->flag & TF_SELECT) && mface->v3) {
			tot += 3;
			if(mface->v4) tot++; 
		}
	}
	if(tot==0) return;

	sb= sortblock= MEM_callocN(sizeof(struct uvvertsort)*tot,"sortsellinkuv");

	mface= me->mface;
	for(a=me->totface, tface=me->tface; a>0; a--, tface++, mface++) {
		if((tface->flag & TF_SELECT) && mface->v3) {
			if(tface->flag & TF_SEL1) sb->flag |= 1;
			sb->v= mface->v1;
			sb->tface= tface;
			sb->tf_sel= 0;
			sb++;
			if(tface->flag & TF_SEL2) sb->flag |= 1;
			sb->v= mface->v2;
			sb->tface= tface;
			sb->tf_sel= 1;
			sb++;
			if(tface->flag & TF_SEL3) sb->flag |= 1;
			sb->v= mface->v3;
			sb->tface= tface;
			sb->tf_sel= 2;
			sb++;
			if(mface->v4) {
				if(tface->flag & TF_SEL4) sb->flag |= 1;
				sb->v= mface->v4;
				sb->tface= tface;
				sb->tf_sel= 3;
				sb++;
			}
		}
	}
	
	/* sort by vertex */
	qsort(sortblock, tot, sizeof(struct uvvertsort), compuvvert);

	sel= 1;
	while(sel) {
		sel= 0;

		/* select all tex vertices that are near a selected tex vertex */
		for (a=0, sb=sortblock; a<tot; a+=vtot, sb+=vtot) {
			vtot= 0;
			for (b=a, sb1=sb; b<tot && sb1->v==sb->v; b++, sb1++)
				vtot++;
			for (b=a, sb1=sb; b<a+vtot; b++, sb1++) {
				if(sb1->flag & 1) continue;

				for (c=a, sb2=sb; c<a+vtot; c++, sb2++) {
					if(!(sb2->flag & 1)) continue;
					uv = sb2->tface->uv[sb2->tf_sel];
					uv1 = sb1->tface->uv[sb1->tf_sel];
					if (fabs(uv[0]-uv1[0]) < limit[0] &&
					    fabs(uv[1]-uv1[1]) < limit[1]) {
						sb1->flag |= 1;
						sel= 1;
						break;
					}
				}
			}
		}

		/* if one tex vert is selected, select the whole tface */
		for (a=0, sb=sortblock; a<tot; a++, sb++) {
			if(sb->flag & 1) {
				sb->tface->flag |= (TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
			}
		}

		/* sync the flags, one bitflag check is enough */
		for (a=0, sb=sortblock; a<tot; a++, sb++) {
			if(sb->tface->flag & TF_SEL1 && !(sb->flag & 1)) {
				sb->flag |= 1;
				sel= 1;
			}
		}
	}
	MEM_freeN(sortblock);

	scrarea_queue_winredraw(curarea);
}

void unlink_selection(void)
{
	Mesh *me;
	TFace *tface;
	MFace *mface;
	int a;

	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);

	mface= me->mface;
	for(a=me->totface, tface= me->tface; a>0; a--, tface++, mface++) {
		if(mface->v3 && tface->flag & TF_SELECT) {
			if(mface->v4) {
				if(~tface->flag & (TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4))
					tface->flag &= ~(TF_SEL1|TF_SEL2|TF_SEL3|TF_SEL4);
			} else {
				if(~tface->flag & (TF_SEL1|TF_SEL2|TF_SEL3))
					tface->flag &= ~(TF_SEL1|TF_SEL2|TF_SEL3);
			}
		}
	}
	
	scrarea_queue_winredraw(curarea);
}

void toggle_uv_select(int mode)
{
	switch(mode){
	case 'f':
		G.sima->flag ^= SI_SELACTFACE;
		break;
	case 's':
		G.sima->flag ^= SI_STICKYUVS; 
		if (G.sima->flag & SI_STICKYUVS) G.sima->flag &= ~SI_LOCALSTICKY;
		break;
	case 'l': 
		 G.sima->flag ^= SI_LOCALSTICKY;
		 if (G.sima->flag & SI_LOCALSTICKY) G.sima->flag &= ~SI_STICKYUVS;
		break;
	case 'o':
		G.sima->flag &= ~SI_STICKYUVS; 
		G.sima->flag &= ~SI_LOCALSTICKY;
		break;
	}
	allqueue(REDRAWIMAGE, 0);
}

void pin_tface_uv(int mode)
{
	Mesh *me;
	TFace *tface;
	MFace *mface;
	int a;
	
	if( is_uv_tface_editing_allowed()==0 ) return;
	me= get_mesh(OBACT);
	
	mface= me->mface;
	tface= me->tface;
	for(a=me->totface; a>0; a--, tface++, mface++) {
		if(mface->v3 && tface->flag & TF_SELECT) {
			if(mode ==1){
				if(tface->flag & TF_SEL1) tface->unwrap |= TF_PIN1;
				if(tface->flag & TF_SEL2) tface->unwrap |= TF_PIN2;
				if(tface->flag & TF_SEL3) tface->unwrap |= TF_PIN3;
				if(mface->v4)
					if(tface->flag & TF_SEL4) tface->unwrap |= TF_PIN4;
			}
			else if (mode ==0){
				if(tface->flag & TF_SEL1) tface->unwrap &= ~TF_PIN1;
				if(tface->flag & TF_SEL2) tface->unwrap &= ~TF_PIN2;
				if(tface->flag & TF_SEL3) tface->unwrap &= ~TF_PIN3;
				if(mface->v4)
				if(tface->flag & TF_SEL4) tface->unwrap &= ~TF_PIN4;
			}
		}
	}
	scrarea_queue_winredraw(curarea);
}