fteqw/engine/gl/glmod_doom.c

#include "quakedef.h"
#ifdef MAP_DOOM
#include "glquake.h"
#include "shader.h"

int SignbitsForPlane (mplane_t *out);
int	PlaneTypeForNormal ( vec3_t normal );

//coded from file specifications provided by:
//Matthew S Fell (msfell@aol.com)
//Unofficial Doom Specs

//(aol suck)

void Doom_SetModelFunc(model_t *mod);
int Doom_SectorNearPoint(vec3_t p);

//assumptions:
//1. That there is a node, and thus two ssectors.
//2. That the user doesn't want textures...
//3. That all segs ssectors for a single sector are all the same.
//4. That ALL sectors are fully enclosed, and not made of two areas.
//5. That no sectors are inside out.

enum {
	THING_PLAYER		= 1,
	THING_PLAYER2		= 2,
	THING_PLAYER3		= 3,
	THING_PLAYER4		= 4,
	THING_DMSPAWN		= 11,

//we need to balance weapons according to ammo types.
	THING_WCHAINSAW		= 2005,	//-> quad
	THING_WSHOTGUN1		= 2001,	//-> ng
	THING_WSHOTGUN2		= 82,	//-> sng
	THING_WCHAINGUN		= 2002,	//-> ssg
	THING_WROCKETL		= 2003,	//-> lightning
	THING_WPLASMA		= 2004,	//-> grenade
	THING_WBFG			= 2006	//-> rocket
} THING_TYPES;

//thing flags
//skill/dm is appears in rather than quake's excuded in.
#define THING_EASY			1
#define THING_MEDIUM		2
#define THING_HARD			4
#define THING_DEAF			8
#define	THING_DEATHMATCH	16
//other bits are ignored



typedef struct {
	short xpos;
	short ypos;
	short angle;
	unsigned short type;
	unsigned short flags;
} dthing_t;

typedef struct {
	short xpos;
	short ypos;
} ddoomvertex_t;

typedef struct {
	float xpos;
	float ypos;
} mdoomvertex_t;

typedef struct {
	unsigned short vert[2];
	unsigned short flags;
	short types;
	short tag;
	unsigned short sidedef[2]; //(0xffff is none for sidedef[1])
} dlinedef_t;
#define LINEDEF_IMPASSABLE		1
#define	LINEDEF_BLOCKMONSTERS	2
#define LINEDEF_TWOSIDED		4
#define LINEDEF_UPPERUNPEGGED	8
#define LINEDEF_LOWERUNPEGGED	16
#define LINEDEF_SECRET			32	//seen as singlesided on automap, does nothing else.
#define LINEDEF_BLOCKSOUND		64
#define LINEDEF_NOTONMAP		128	//doesn't appear on automap.
#define LINEDEF_STARTONMAP		256
//others are ignored.

typedef struct {
	short texx;
	short texy;
	char uppertex[8];
	char lowertex[8];
	char middletex[8];
	unsigned short sector;
} dsidedef_t;
typedef struct {
	float texx;
	float texy;
	int uppertex;
	int lowertex;
	int middletex;
	unsigned short sector;
} msidedef_t;

typedef struct {	//figure out which linedef to use and throw the rest away.
	unsigned short	vert[2];
	short	angle;
	unsigned short	linedef;
	short	direction;
	short	offset;
} dseg_t;

typedef struct {
	unsigned short	vert[2];
	unsigned short	linedef;
	short	direction;
	unsigned short Partner;	//the one on the other side of the owner's linedef
} dgl_seg1_t;

typedef struct {
	unsigned int	vert[2];
	unsigned short	linedef;
	short	direction;
	unsigned int Partner;	//the one on the other side of the owner's linedef
} dgl_seg3_t;

typedef struct {
	unsigned short segcount;
	unsigned short first;
} dssector_t;

typedef struct {
	short x;
	short y;
	short dx;
	short dy;
	short y1upper;
	short y1lower;
	short x1lower;
	short x1upper;
	short y2upper;
	short y2lower;
	short x2lower;
	short x2upper;
	unsigned short node1;
	unsigned short node2;
} ddoomnode_t;
#define NODE_IS_SSECTOR	0x8000

typedef struct {
	short floorheight;
	short ceilingheight;
	char floortexture[8];
	char ceilingtexture[8];
	short lightlevel;
	short specialtype;
	short tag;
} dsector_t;

typedef struct {
	int visframe;
	int floortex;
	int ceilingtex;

	short floorheight;
	short ceilingheight;

	qbyte lightlev;
	qbyte pad;
	int numflattris;
	short tag;
	short specialtype;

	unsigned short *flats;
} msector_t;


typedef struct {
	short xorg;
	short yorg;
	short columns;
	short rows;
} blockmapheader_t;

ddoomnode_t		*nodel;
dssector_t		*ssectorsl;
dthing_t			*thingsl;
mdoomvertex_t	*vertexesl;
dgl_seg3_t		*segsl;
dlinedef_t		*linedefsl;
msidedef_t		*sidedefsm;
msector_t		*sectorm;
plane_t			*nodeplanes;
plane_t			*lineplanes;
blockmapheader_t *blockmapl;
unsigned short	*blockmapofs;
unsigned int nodec;
unsigned int sectorc;
unsigned int segsc;
unsigned int ssectorsc;
unsigned int thingsc;
unsigned int linedefsc;
unsigned int sidedefsc;
unsigned int vertexesc;
unsigned int vertexsglbase;

extern model_t	*loadmodel;
extern char loadname[];


typedef struct
{
	char name[8];
	shader_t *shader;
	unsigned short width;
	unsigned short height;
	batch_t batch;
	mesh_t *meshptr;
	mesh_t mesh;
	int maxverts;
	int maxindicies;
} gldoomtexture_t;
gldoomtexture_t *gldoomtextures;
int numgldoomtextures;


////////////////////////////////////////////////////////////////////////////////////////////
//physics

/*walk the bsp tree*/
int Doom_SectorNearPoint(vec3_t p)
{
	ddoomnode_t *node;
	plane_t *plane;
	int num;
	int seg;
	float d;
	num = nodec-1;
	while (1)
	{
		if (num & NODE_IS_SSECTOR)
		{
			num -= NODE_IS_SSECTOR;
			for (seg = ssectorsl[num].first; seg < ssectorsl[num].first + ssectorsl[num].segcount; seg++)
				if (segsl[seg].linedef != 0xffff)
					break;

			return sidedefsm[linedefsl[segsl[seg].linedef].sidedef[segsl[seg].direction]].sector;
		}

		node = nodel + num;
		plane = nodeplanes + num;
		
//		if (plane->type < 3)
//			d = p[plane->type] - plane->dist;
//		else
			d = DotProduct (plane->normal, p) - plane->dist;
		if (d < 0)
			num = node->node2;
		else
			num = node->node1;
	}
	
	return num;
}

int Doom_PointContents(model_t *model, vec3_t axis[3], vec3_t p)
{
	int sec = Doom_SectorNearPoint(p);
	if (p[2] < sectorm[sec].floorheight)
		return FTECONTENTS_SOLID;
	if (p[2] > sectorm[sec].ceilingheight)
		return FTECONTENTS_SOLID;
	return FTECONTENTS_EMPTY;
}

qboolean Doom_Trace(model_t *model, int hulloverride, int frame, vec3_t axis[3], vec3_t start, vec3_t end, vec3_t mins, vec3_t maxs, int contentstype, trace_t *trace)
{
#if 0
#define TRACESTEP	16
	unsigned short *linedefs;
	dlinedef_t *ld;
	int bmi, obmi;
	vec3_t delta;
	int sec1 = Doom_SectorNearPoint(start);
	vec3_t p1, pointonplane, ofs;
	float d1, d2, c1, c2, planedist;
	plane_t *lp;
	mdoomvertex_t *v1, *v2;
	int j;
	float p2f;

	float clipfrac;
#define	DIST_EPSILON	(0.03125)

//	Con_Printf("%i\n", sec1);

	if (start[2] < sectorm[sec1].floorheight-mins[2])	//whoops, started outside... ?
	{
		trace->fraction = 0;
		trace->allsolid = trace->startsolid = true;
		trace->endpos[0] = start[0];
		trace->endpos[1] = start[1];
		trace->endpos[2] = start[2];	//yeah, we do mean this - startsolid
//		if (IS_NAN(trace->endpos[2]))
//			Con_Printf("Nanny\n");
		trace->plane.normal[0] = 0;
		trace->plane.normal[1] = 0;
		trace->plane.normal[2] = 1;
		trace->plane.dist = sectorm[sec1].floorheight-mins[2];

		return false;
	}
	if (start[2] > sectorm[sec1].ceilingheight-maxs[2])	//whoops, started outside... ?
	{
		trace->fraction = 0;
		trace->allsolid = trace->startsolid = true;
		trace->endpos[0] = start[0];
		trace->endpos[1] = start[1];
		trace->endpos[2] = start[2];
		trace->plane.normal[0] = 0;
		trace->plane.normal[1] = 0;
		trace->plane.normal[2] = -1;
		trace->plane.dist = -(sectorm[sec1].ceilingheight-maxs[2]);
		return false;
	}

	obmi = -1;
	VectorSubtract(end, start, delta);
	p2f = Length(delta)+DIST_EPSILON;
	if (IS_NAN(p2f) || p2f > 100000)
		p2f = 100000;
	VectorNormalize(delta);

	trace->endpos[0] = end[0];
	trace->endpos[1] = end[1];
	trace->endpos[2] = end[2];

	trace->fraction = 1;
	while(1)
	{
		bmi = ((int)p1[0] - blockmapl->xorg)/128 + (((int)p1[1] - blockmapl->yorg)/128)*blockmapl->columns;
//		Con_Printf("%i of %i ", bmi, blockmapl->rows*blockmapl->columns);
		if (bmi >= 0 && bmi < blockmapl->rows*blockmapl->columns)
		if (bmi != obmi)
		{
#if 1
			short dummy;
			linedefs = &dummy;
			for (dummy = 0; dummy < linedefsc; dummy++)
#else
			for(linedefs = (short*)blockmapl + blockmapofs[bmi]+1; *linedefs != 0xffff; linedefs++)
#endif
			{
				ld = linedefsl + *linedefs;
				if (ld->sidedef[1] != 0xffff)
				{
					if (sectorm[sidedefsm[ld->sidedef[0]].sector].floorheight == sectorm[sidedefsm[ld->sidedef[1]].sector].floorheight &&
						sectorm[sidedefsm[ld->sidedef[0]].sector].ceilingheight == sectorm[sidedefsm[ld->sidedef[1]].sector].ceilingheight)
						continue;
				}
				
				lp = lineplanes + *linedefs;

				if (1)
				{	//figure out how far to move the plane out by
					for (j=0 ; j<2 ; j++)
					{
						if (lp->normal[j] < 0)
							ofs[j] = maxs[j];
						else
							ofs[j] = mins[j];
					}
					ofs[2] = 0;
					planedist = lp->dist - DotProduct (ofs, lp->normal);
				}
				else
					planedist = lp->dist;

				d1 = DotProduct(lp->normal, start) - (planedist);
				d2 = DotProduct(lp->normal, end) - (planedist);
				if (d1 > 0 && d2 > 0)
					continue;	//both points on the front side.
				if (d1 < 0)	//start on back side
				{
					if (ld->sidedef[1] != 0xffff)	//two sided (optimisation)
					{
						planedist = -planedist+lp->dist;
						if (/*d1 < planedist*-1 &&*/ d1 > planedist*2)
						{	//right, we managed to end up just on the other side of a wall's plane.
							v1 = &vertexesl[ld->vert[0]];
							v2 = &vertexesl[ld->vert[1]];
							if (!(d1 - d2))
								continue;
							if (d1<0)	//back to front.
								c1 = (d1+DIST_EPSILON) / (d1 - d2);
							else
								c1 = (d1-DIST_EPSILON) / (d1 - d2);
							c2 = 1-c1;
							pointonplane[0] = start[0]*c2 + p2[0]*c1;
/*							if (pointonplane[0] > v1->xpos+DIST_EPSILON*2+hull->clip_maxs[0] && pointonplane[0] > v2->xpos+DIST_EPSILON*2+hull->clip_maxs[0])
								continue;
							if (pointonplane[0] < v1->xpos-DIST_EPSILON*2+hull->clip_mins[0] && pointonplane[0] < v2->xpos-DIST_EPSILON*2+hull->clip_mins[0])
								continue;
*/							pointonplane[1] = start[1]*c2 + p2[1]*c1;
/*							if (pointonplane[1] > v1->ypos+DIST_EPSILON*2+hull->clip_maxs[1] && pointonplane[1] > v2->ypos+DIST_EPSILON*2+hull->clip_maxs[1])
								continue;
							if (pointonplane[1] < v1->ypos-DIST_EPSILON*2+hull->clip_mins[1] && pointonplane[1] < v2->ypos-DIST_EPSILON*2+hull->clip_mins[1])
								continue;
*/
							pointonplane[2] = start[2]*c2 + p2[2]*c1;

							Con_Printf("Started in wall\n");
							j = sidedefsm[ld->sidedef[d1 < planedist]].sector;
							//yup, we are in the thing
							//prevent ourselves from entering the back-sector's floor/ceiling
							if (pointonplane[2] < sectorm[j].floorheight-hull->clip_mins[2])	//whoops, started outside... ?
							{
								Con_Printf("Started in floor\n");
								trace->allsolid = trace->startsolid = false;
								trace->endpos[2] = sectorm[j].floorheight-hull->clip_mins[2];
								trace->fraction = fabs(trace->endpos[2] - start[2]) / fabs(p2[2] - start[2]);
								trace->endpos[0] = start[0]+delta[0]*trace->fraction*p2f;
								trace->endpos[1] = start[1]+delta[1]*trace->fraction*p2f;
						//		if (IS_NAN(trace->endpos[2]))
						//			Con_Printf("Nanny\n");
								trace->plane.normal[0] = 0;
								trace->plane.normal[1] = 0;
								trace->plane.normal[2] = 1;
								trace->plane.dist = sectorm[j].floorheight-hull->clip_mins[2];

								continue;
							}
							if (pointonplane[2] > sectorm[j].ceilingheight-hull->clip_maxs[2])	//whoops, started outside... ?
							{
								Con_Printf("Started in ceiling\n");
								trace->allsolid = trace->startsolid = false;
								trace->endpos[0] = pointonplane[0];
								trace->endpos[1] = pointonplane[1];
								trace->endpos[2] = sectorm[j].ceilingheight-hull->clip_maxs[2];
								trace->fraction = fabs(trace->endpos[2] - start[2]) / fabs(p2[2] - start[2]);
								trace->plane.normal[0] = 0;
								trace->plane.normal[1] = 0;
								trace->plane.normal[2] = -1;
								trace->plane.dist = -(sectorm[j].ceilingheight-hull->clip_maxs[2]);
								continue;
							}
						}
					}
					if (d2 < 0)
						continue;	//both points on the reverse side.
				}

				//line crosses plane.

				v1 = &vertexesl[ld->vert[0]];
				v2 = &vertexesl[ld->vert[1]];

				if (d1<0)	//back to front.
				{
					if (ld->sidedef[1] == 0xffff)
						continue;	//hack to allow them to pass
					c1 = (d1+DIST_EPSILON) / (d1 - d2);
				}
				else
					c1 = (d1-DIST_EPSILON) / (d1 - d2);
				c2 = 1-c1;
				pointonplane[0] = start[0]*c2 + p2[0]*c1;
				if (pointonplane[0] > v1->xpos+DIST_EPSILON*2+hull->clip_maxs[0] && pointonplane[0] > v2->xpos+DIST_EPSILON*2+hull->clip_maxs[0])
					continue;
				if (pointonplane[0] < v1->xpos-DIST_EPSILON*2+hull->clip_mins[0] && pointonplane[0] < v2->xpos-DIST_EPSILON*2+hull->clip_mins[0])
					continue;
				pointonplane[1] = start[1]*c2 + p2[1]*c1;
				if (pointonplane[1] > v1->ypos+DIST_EPSILON*2+hull->clip_maxs[1] && pointonplane[1] > v2->ypos+DIST_EPSILON*2+hull->clip_maxs[1])
					continue;
				if (pointonplane[1] < v1->ypos-DIST_EPSILON*2+hull->clip_mins[1] && pointonplane[1] < v2->ypos-DIST_EPSILON*2+hull->clip_mins[1])
					continue;
				pointonplane[2] = start[2]*c2 + p2[2]*c1;

				if (ld->flags & LINEDEF_IMPASSABLE || ld->sidedef[1] == 0xffff)	//unconditionally unpassable.
				{	//unconditionally clipped.
				}
				else
				{	//ensure that the side we are passing on to passes the clip (no ceiling/floor clips happened first)
					msector_t *sec2;

					if (d1<0)
						sec2 = &sectorm[sidedefsm[ld->sidedef[1]].sector];
					else
						sec2 = &sectorm[sidedefsm[ld->sidedef[0]].sector];

					if (pointonplane[2] < sec2->floorheight-hull->clip_mins[2])
					{	//hit the floor first.
						c1 = fabs(sectorm[sec1].floorheight-hull->clip_mins[2] - start[2]);
						c2 = fabs(p2[2] - start[2]);
						if (!c2)
							c1 = 1;
						else
							c1 = (c1-DIST_EPSILON) / c2;
						if (trace->fraction > c1)
						{
//							Con_Printf("Hit floor\n");
							trace->fraction = c1;
							trace->allsolid = trace->startsolid = true;
							trace->endpos[0] = start[0] + trace->fraction*(p2[0]-start[0]);
							trace->endpos[1] = start[1] + trace->fraction*(p2[1]-start[1]);
							trace->endpos[2] = start[2] + trace->fraction*(p2[2]-start[2]);
							trace->plane.normal[0] = 0;
							trace->plane.normal[1] = 0;
							trace->plane.normal[2] = 1;
							trace->plane.dist = sectorm[sec1].floorheight-hull->clip_mins[2];
						}
						continue;
					}

					if (pointonplane[2] > sec2->ceilingheight-hull->clip_maxs[2])
					{	//hit the floor first.
						c1 = fabs((sectorm[sec1].ceilingheight-hull->clip_maxs[2]) - start[2]);
						c2 = fabs(p2[2] - start[2]);
						if (!c2)
							c1 = 1;
						else
							c1 = (c1-DIST_EPSILON) / c2;


						if (trace->fraction > c1)
						{
//							Con_Printf("Hit ceiling\n");
							trace->fraction = c1;
							trace->allsolid = trace->startsolid = true;
							trace->endpos[0] = start[0] + trace->fraction*(p2[0]-start[0]);
							trace->endpos[1] = start[1] + trace->fraction*(p2[1]-start[1]);
							trace->endpos[2] = start[2] + trace->fraction*(p2[2]-start[2]);
							trace->plane.normal[0] = 0;
							trace->plane.normal[1] = 0;
							trace->plane.normal[2] = -1;
							trace->plane.dist = -(sectorm[sec1].ceilingheight-hull->clip_maxs[2]);
						}
						continue;
					}

					if (d1<0)
						sec2 = &sectorm[sidedefsm[ld->sidedef[0]].sector];
					else
						sec2 = &sectorm[sidedefsm[ld->sidedef[1]].sector];

					if(sec2->ceilingheight == sec2->floorheight)
						sec2->ceilingheight += 64;

					if (pointonplane[2] > sec2->floorheight-hull->clip_mins[2] &&
						pointonplane[2] < sec2->ceilingheight-hull->clip_maxs[2])
					{
						Con_Printf("Two sided passed\n");
						continue;
					}

//					Con_Printf("blocked by two sided line\n");
//					sec2->floorheight--;
				}

				if (d1<0)	//back to front.
					c1 = (d1+DIST_EPSILON) / (d1 - d2);
				else
					c1 = (d1-DIST_EPSILON) / (d1 - d2);


				clipfrac = c1;

				if (clipfrac < 0)
					clipfrac = 0;
				if (clipfrac > 1)
					clipfrac = 1;

				if (trace->fraction > clipfrac)
				{
					trace->fraction = clipfrac;
					VectorMA(pointonplane, 0, lp->normal, trace->endpos);
					VectorMA(trace->endpos, -0.1, delta, trace->endpos);
//					if (IS_NAN(trace->endpos[2]))
//						Con_Printf("Buggy clipping\n");
					VectorCopy(lp->normal, trace->plane.normal);
					trace->plane.dist = planedist;
//					if (IS_NAN(trace->plane.normal[2]))
//						Con_Printf("Buggy clipping\n");

					if (clipfrac)
					Con_Printf("Clip Wall %f\n", clipfrac);
				}
			}
			
			obmi = bmi;
		}

		p1f += TRACESTEP;
		if (p1f >= p2f)
			break;

		VectorMA(p1, TRACESTEP, delta, p1);
	}

//	VectorMA(start, p2f*trace->fraction, delta, p2);

	if (p2[2] != start[2])
	{
		if (sec1 == Doom_SectorNearPoint(p2))	//special test.
		{
			if (p2[2] <= sectorm[sec1].floorheight-hull->clip_mins[2])	//whoops, started outside... ?
			{
				p1f = fabs(sectorm[sec1].floorheight-hull->clip_mins[2] - start[2]);
				p2f = fabs(p2[2] - start[2]);
				if (!p2f)
					c1 = 1;
				else
					c1 = (p1f-DIST_EPSILON) / p2f;
				if (trace->fraction > c1)
				{
					trace->fraction = c1;
					trace->allsolid = trace->startsolid = false;
					trace->endpos[0] = start[0] + trace->fraction*(p2[0]-start[0]);
					trace->endpos[1] = start[1] + trace->fraction*(p2[1]-start[1]);
					trace->endpos[2] = start[2] + trace->fraction*(p2[2]-start[2]);
					trace->plane.normal[0] = 0;
					trace->plane.normal[1] = 0;
					trace->plane.normal[2] = 1;
					trace->plane.dist = sectorm[sec1].floorheight-hull->clip_mins[2];
				}

//				if (IS_NAN(trace->endpos[2]))
//					Con_Printf("Nanny\n");
			}
			if (p2[2] >= sectorm[sec1].ceilingheight-hull->clip_maxs[2])	//whoops, started outside... ?
			{
				p1f = fabs(sectorm[sec1].ceilingheight-hull->clip_maxs[2] - start[2]);
				p2f = fabs(p2[2] - start[2]);
				if (!p2f)
					c1 = 1;
				else
					c1 = (p1f-DIST_EPSILON) / p2f;
				if (trace->fraction > c1)
				{
					trace->fraction = c1;
					trace->allsolid = trace->startsolid = false;
					trace->endpos[0] = start[0] + trace->fraction*(p2[0]-start[0]);
					trace->endpos[1] = start[1] + trace->fraction*(p2[1]-start[1]);
					trace->endpos[2] = start[2] + trace->fraction*(p2[2]-start[2]);
					trace->plane.normal[0] = 0;
					trace->plane.normal[1] = 0;
					trace->plane.normal[2] = -1;
					trace->plane.dist = -(sectorm[sec1].ceilingheight-hull->clip_maxs[2]);
				}

//				if (IS_NAN(trace->endpos[2]))
//					Con_Printf("Nanny\n");
			}
		}
	}

	//we made it all the way through. yay.

	trace->allsolid = trace->startsolid = false;
//Con_Printf("total = %f\n", trace->fraction);
	return trace->fraction==1;
#endif
}

















#ifndef SERVERONLY
qbyte doompalette[768];
static qboolean paletteloaded;

void Doom_LoadPalette(void)
{
	char *file;
	int greyscale;
	if (!paletteloaded)
	{
		paletteloaded = true;
		file = FS_LoadMallocFile("wad/playpal");
		if (file)
		{
			memcpy(doompalette, file, 768);
			Z_Free(file);
		}
		else
		{
			for (greyscale = 0; greyscale < 256; greyscale++)
			{
				doompalette[greyscale*3+0] = greyscale;
				doompalette[greyscale*3+1] = greyscale;
				doompalette[greyscale*3+2] = greyscale;
			}
		}
	}
}
#endif
int Doom_LoadFlat(char *flatname)
{
#ifndef SERVERONLY
	char *file;
	char texname[64];
	int texnum;

	sprintf(texname, "flats/%-.8s", flatname);

	for (texnum = 0; texnum < numgldoomtextures; texnum++)
	{
		if (!strcmp(gldoomtextures[texnum].name, texname))
			return texnum;
	}
	
	gldoomtextures = BZ_Realloc(gldoomtextures, sizeof(*gldoomtextures)*((numgldoomtextures+16)&~15));
	memset(gldoomtextures + numgldoomtextures, 0, sizeof(gldoomtextures[numgldoomtextures]));
	numgldoomtextures++;

	strncpy(gldoomtextures[texnum].name, texname, 8);

	gldoomtextures[texnum].shader = R_RegisterShader(texname, "{\n{\nmap $diffuse\nrgbgen vertex\nalphagen vertex\n}\n}\n");

	gldoomtextures[texnum].width = 64;
	gldoomtextures[texnum].height = 64;
	gldoomtextures[texnum].meshptr = &gldoomtextures[texnum].mesh;
	gldoomtextures[texnum].batch.mesh = &gldoomtextures[texnum].meshptr;
	gldoomtextures[texnum].batch.next = loadmodel->batches[gldoomtextures[texnum].shader->sort];
	loadmodel->batches[gldoomtextures[texnum].shader->sort] = &gldoomtextures[texnum].batch;

	file = FS_LoadMallocFile(texname);
	if (file)
	{
		gldoomtextures[texnum].shader->defaulttextures.base = R_LoadTexture8Pal24(texname, 64, 64, file, doompalette, 0);
		Z_Free(file);
	}

	return texnum;
#else
	return 0;
#endif
}

#ifndef SERVERONLY
static void GLR_DrawWall(int texnum, int s, int t, float x1, float y1, float z1, float x2, float y2, float z2, qboolean unpegged, unsigned int colour4b)
{
	gldoomtexture_t *tex = gldoomtextures+texnum;
	mesh_t *mesh = &tex->mesh;
	float len = sqrt((x1-x2)*(x1-x2) + (y1-y2)*(y1-y2));
	float s1, s2;
	float t1, t2;
	unsigned int col;

	s1 = s/tex->width;
	s2 = s1 + len/tex->width;

	if (unpegged)
	{
		t2 = t/tex->height;
		t1 = t2 - (z2-z1)/tex->height;
	}
	else
	{
		t1 = t/tex->height;
		t2 = t1 + (z2-z1)/tex->height;
	}
	t1 = 0;
	t2 = 1;

	if (mesh->numvertexes+4 > tex->maxverts)
	{
		tex->maxverts = mesh->numvertexes+4;
		mesh->colors4b_array = BZ_Realloc(mesh->colors4b_array, sizeof(*mesh->colors4b_array) * tex->maxverts);
		mesh->xyz_array = BZ_Realloc(mesh->xyz_array, sizeof(*mesh->xyz_array) * tex->maxverts);
		mesh->st_array = BZ_Realloc(mesh->st_array, sizeof(*mesh->st_array) * tex->maxverts);
	}
	if (mesh->numindexes+6 > tex->maxindicies)
	{
		tex->maxindicies = mesh->numindexes+6;
		mesh->indexes = BZ_Realloc(mesh->indexes, sizeof(*mesh->indexes) * tex->maxindicies);
	}

	col = colour4b * 0x01010101;
	((unsigned char*)&col)[3] = 0xff;
	*(unsigned int*)mesh->colors4b_array[mesh->numvertexes+0] = col;
	*(unsigned int*)mesh->colors4b_array[mesh->numvertexes+1] = col;
	*(unsigned int*)mesh->colors4b_array[mesh->numvertexes+2] = col;
	*(unsigned int*)mesh->colors4b_array[mesh->numvertexes+3] = col;
	VectorSet(mesh->xyz_array[mesh->numvertexes+0], x1, y1, z1);
	VectorSet(mesh->xyz_array[mesh->numvertexes+1], x1, y1, z2);
	VectorSet(mesh->xyz_array[mesh->numvertexes+2], x2, y2, z2);
	VectorSet(mesh->xyz_array[mesh->numvertexes+3], x2, y2, z1);
	Vector2Set(mesh->st_array[mesh->numvertexes+0], s1, t2);
	Vector2Set(mesh->st_array[mesh->numvertexes+1], s1, t1);
	Vector2Set(mesh->st_array[mesh->numvertexes+2], s2, t1);
	Vector2Set(mesh->st_array[mesh->numvertexes+3], s2, t2);

	mesh->indexes[mesh->numindexes+0] = mesh->numvertexes+0;
	mesh->indexes[mesh->numindexes+1] = mesh->numvertexes+1;
	mesh->indexes[mesh->numindexes+2] = mesh->numvertexes+2;

	mesh->indexes[mesh->numindexes+3] = mesh->numvertexes+0;
	mesh->indexes[mesh->numindexes+4] = mesh->numvertexes+2;
	mesh->indexes[mesh->numindexes+5] = mesh->numvertexes+3;

	mesh->numvertexes += 4;
	mesh->numindexes += 6;

	BE_DrawMesh_Single(tex->shader, mesh, NULL, &tex->shader->defaulttextures, 0);
}

static void GLR_DrawFlats(int floortexnum, int floorheight, int ceiltexnum, int ceilheight, int numverts, unsigned short *verts, unsigned int colour4b)
{
	mesh_t *mesh;
	unsigned int col;
	unsigned int v, i;

	//floor
	{
		gldoomtexture_t *floortex = gldoomtextures + floortexnum;
		mesh = &floortex->mesh;
		if (mesh->numvertexes+numverts > floortex->maxverts)
		{
			floortex->maxverts = mesh->numvertexes+numverts;
			mesh->colors4b_array = BZ_Realloc(mesh->colors4b_array, sizeof(*mesh->colors4b_array) * floortex->maxverts);
			mesh->xyz_array = BZ_Realloc(mesh->xyz_array, sizeof(*mesh->xyz_array) * floortex->maxverts);
			mesh->st_array = BZ_Realloc(mesh->st_array, sizeof(*mesh->st_array) * floortex->maxverts);
		}
		if (mesh->numindexes+numverts > floortex->maxindicies)
		{
			floortex->maxindicies = mesh->numindexes+numverts;
			mesh->indexes = BZ_Realloc(mesh->indexes, sizeof(*mesh->indexes) * floortex->maxindicies);
		}

		col = colour4b * 0x01010101;
		((unsigned char*)&col)[3] = 0xff;

		for (i = 0; i < numverts; i++)
		{
			v = verts[i];
			VectorSet(mesh->xyz_array[mesh->numvertexes+i], vertexesl[v].xpos, vertexesl[v].ypos, floorheight);
			Vector2Set(mesh->st_array[mesh->numvertexes+i], vertexesl[v].xpos/64.0f, vertexesl[v].ypos/64.0f);
			*(unsigned int*)mesh->colors4b_array[mesh->numvertexes+i] = col;
		}

		for (i = 0; i < numverts; i++)
		{
			mesh->indexes[mesh->numindexes+i] = mesh->numvertexes+i;
		}

		mesh->numvertexes += numverts;
		mesh->numindexes += numverts;

		BE_DrawMesh_Single(floortex->shader, mesh, NULL, &floortex->shader->defaulttextures, 0);
	}

	//ceiling
	{
		gldoomtexture_t *ceiltex = gldoomtextures + ceiltexnum;
		mesh = &ceiltex->mesh;
		if (mesh->numvertexes+numverts > ceiltex->maxverts)
		{
			ceiltex->maxverts = mesh->numvertexes+numverts;
			mesh->colors4b_array = BZ_Realloc(mesh->colors4b_array, sizeof(*mesh->colors4b_array) * ceiltex->maxverts);
			mesh->xyz_array = BZ_Realloc(mesh->xyz_array, sizeof(*mesh->xyz_array) * ceiltex->maxverts);
			mesh->st_array = BZ_Realloc(mesh->st_array, sizeof(*mesh->st_array) * ceiltex->maxverts);
		}
		if (mesh->numindexes+numverts > ceiltex->maxindicies)
		{
			ceiltex->maxindicies = mesh->numindexes+numverts;
			mesh->indexes = BZ_Realloc(mesh->indexes, sizeof(*mesh->indexes) * ceiltex->maxindicies);
		}

		col = colour4b * 0x01010101;
		((unsigned char*)&col)[3] = 0xff;

		for (i = 0; i < numverts; i++)
		{
			v = verts[numverts-1-i];
			VectorSet(mesh->xyz_array[mesh->numvertexes+i], vertexesl[v].xpos, vertexesl[v].ypos, ceilheight);
			Vector2Set(mesh->st_array[mesh->numvertexes+i], vertexesl[v].xpos/64.0f, vertexesl[v].ypos/64.0f);
			*(unsigned int*)mesh->colors4b_array[mesh->numvertexes+i] = col;
		}

		for (i = 0; i < numverts; i++)
		{
			mesh->indexes[mesh->numindexes+i] = mesh->numvertexes+i;
		}

		mesh->numvertexes += numverts;
		mesh->numindexes += numverts;

		BE_DrawMesh_Single(ceiltex->shader, mesh, NULL, &ceiltex->shader->defaulttextures, 0);
	}
}

static void GLR_DrawSSector(unsigned int ssec)
{
	short v0, v1;
	int sd;
	dlinedef_t *ld;
	int seg;
	msector_t *sec, *sec2;

	for (seg = ssectorsl[ssec].first + ssectorsl[ssec].segcount-1; seg >= ssectorsl[ssec].first; seg--)
		if (segsl[seg].linedef != 0xffff)
			break;
	sec = sectorm + sidedefsm[linedefsl[segsl[seg].linedef].sidedef[segsl[seg].direction]].sector;

	if (sec->visframe != r_visframecount)
	{
		GLR_DrawFlats(sec->floortex, sec->floorheight, sec->ceilingtex, sec->ceilingheight, sec->numflattris*3, sec->flats, sec->lightlev);

		sec->visframe = r_visframecount;
	}
	for (seg = ssectorsl[ssec].first + ssectorsl[ssec].segcount-1; seg >= ssectorsl[ssec].first; seg--)
	{
		if (segsl[seg].linedef == 0xffff)
			continue;

		v0 = segsl[seg].vert[0];
		v1 = segsl[seg].vert[1];
		if (v0==v1)
			continue;
		ld = linedefsl + segsl[seg].linedef;
		sd = ld->sidedef[segsl[seg].direction];

		if (ld->sidedef[1] != 0xffff)	//we can see through this linedef
		{
			sec2 = sectorm + sidedefsm[ld->sidedef[1-segsl[seg].direction]].sector;

			if (sec->floorheight < sec2->floorheight)
			{
				GLR_DrawWall(sidedefsm[sd].lowertex, 
					sidedefsm[ld->sidedef[1-segsl[seg].direction]].texx,
					sidedefsm[ld->sidedef[1-segsl[seg].direction]].texy,
					vertexesl[v0].xpos, vertexesl[v0].ypos, sec->floorheight,
					vertexesl[v1].xpos, vertexesl[v1].ypos, sec2->floorheight, ld->flags & LINEDEF_LOWERUNPEGGED, sec->lightlev);
			}

			if (sec->ceilingheight > sec2->ceilingheight)
			{
				GLR_DrawWall(sidedefsm[sd].uppertex, 
					sidedefsm[ld->sidedef[1-segsl[seg].direction]].texx,
					sidedefsm[ld->sidedef[1-segsl[seg].direction]].texy,
					vertexesl[v0].xpos, vertexesl[v0].ypos, sec2->ceilingheight,
					vertexesl[v1].xpos, vertexesl[v1].ypos, sec->ceilingheight, ld->flags & LINEDEF_UPPERUNPEGGED, sec->lightlev);
			}

			if (sidedefsm[sd].middletex)
			{
				GLR_DrawWall(sidedefsm[sd].middletex, 
					sidedefsm[ld->sidedef[segsl[seg].direction]].texx,
					sidedefsm[ld->sidedef[segsl[seg].direction]].texy,
					vertexesl[v1].xpos, vertexesl[v1].ypos, (sec2->ceilingheight < sec->ceilingheight)?sec2->ceilingheight:sec->ceilingheight,
					vertexesl[v0].xpos, vertexesl[v0].ypos, (sec2->floorheight > sec->floorheight)?sec2->floorheight:sec->floorheight, false, sec->lightlev);
			}
		}
		else
		{	//solid wall, draw full wall.

			GLR_DrawWall(sidedefsm[sd].middletex, 
				sidedefsm[ld->sidedef[segsl[seg].direction]].texx,
				sidedefsm[ld->sidedef[segsl[seg].direction]].texy,
				vertexesl[v0].xpos, vertexesl[v0].ypos, sec->floorheight,
				vertexesl[v1].xpos, vertexesl[v1].ypos, sec->ceilingheight, false, sec->lightlev);
		}
	}
}

mplane_t	frustum2d[2];
static int Box2DOnPlaneSide (short emins[2], short emaxs[2], mplane_t *p)
{
	float	dist1, dist2;
	int		sides;

// general case
	switch (p->signbits)
	{
	case 0:
dist1 = p->normal[0]*emaxs[0] + p->normal[1]*emaxs[1];
dist2 = p->normal[0]*emins[0] + p->normal[1]*emins[1];
		break;
	case 1:
dist1 = p->normal[0]*emins[0] + p->normal[1]*emaxs[1];
dist2 = p->normal[0]*emaxs[0] + p->normal[1]*emins[1];
		break;
	case 2:
dist1 = p->normal[0]*emaxs[0] + p->normal[1]*emins[1];
dist2 = p->normal[0]*emins[0] + p->normal[1]*emaxs[1];
		break;
	case 3:
dist1 = p->normal[0]*emins[0] + p->normal[1]*emins[1];
dist2 = p->normal[0]*emaxs[0] + p->normal[1]*emaxs[1];
		break;
	case 4:
dist1 = p->normal[0]*emaxs[0] + p->normal[1]*emaxs[1];
dist2 = p->normal[0]*emins[0] + p->normal[1]*emins[1];
		break;
	case 5:
dist1 = p->normal[0]*emins[0] + p->normal[1]*emaxs[1];
dist2 = p->normal[0]*emaxs[0] + p->normal[1]*emins[1];
		break;
	case 6:
dist1 = p->normal[0]*emaxs[0] + p->normal[1]*emins[1];
dist2 = p->normal[0]*emins[0] + p->normal[1]*emaxs[1];
		break;
	case 7:
dist1 = p->normal[0]*emins[0] + p->normal[1]*emins[1];
dist2 = p->normal[0]*emaxs[0] + p->normal[1]*emaxs[1];
		break;
	default:
		dist1 = dist2 = 0;		// shut up compiler
//		BOPS_Error ();
		break;
	}

	sides = 0;
	if (dist1 >= p->dist)
		sides = 1;
	if (dist2 < p->dist)
		sides |= 2;

#ifdef PARANOID
if (sides == 0)
	Sys_Error ("Box2DOnPlaneSide: sides==0");
#endif

	return sides;
}
static qboolean R_Cull2DBox (short mins_x, short mins_y, short maxs_x, short maxs_y)
{
	short mins[2], maxs[2];
	int		i;
//return false;
	mins[0] = mins_x;
	mins[1] = mins_y;
	maxs[0] = maxs_x;
	maxs[1] = maxs_y;

	for (i=0 ; i<2 ; i++)
		if (Box2DOnPlaneSide (mins, maxs, &frustum2d[i]) == 2)
			return true;
	return false;
}

void R_Set2DFrustum (void)
{
	int		i;
	vec3_t vpn, vright, vup, viewang;

	if ((int)r_novis.value & 4)
		return;

	viewang[0] = 0;
	viewang[1] = r_refdef.viewangles[1];
	viewang[2] = 0;
	AngleVectors (viewang, vpn, vright, vup);

/*	if (r_refdef.fov_x == 90) 
	{
		// front side is visible

		VectorAdd (vpn, vright, frustum2d[0].normal);
		VectorSubtract (vpn, vright, frustum2d[1].normal);
	}
	else*/
	{

		// rotate VPN right by FOV_X/2 degrees
		RotatePointAroundVector( frustum2d[0].normal, vup, vpn, -(90-r_refdef.fov_x / 2 ) );
		// rotate VPN left by FOV_X/2 degrees
		RotatePointAroundVector( frustum2d[1].normal, vup, vpn, 90-r_refdef.fov_x / 2 );
	}

	for (i=0 ; i<2 ; i++)
	{
		frustum2d[i].type = PLANE_ANYZ;
		frustum2d[i].dist = DotProduct (r_origin, frustum2d[i].normal);
		frustum2d[i].signbits = SignbitsForPlane (&frustum2d[i]);
	}
}


static void GLR_RecursiveDoomNode(unsigned int node)
{
	if (node & NODE_IS_SSECTOR)
	{
		GLR_DrawSSector(node & ~NODE_IS_SSECTOR);		

		return;
	}

	if (!R_Cull2DBox(nodel[node].x1lower, nodel[node].y1lower, nodel[node].x1upper, nodel[node].y1upper)||1)
		GLR_RecursiveDoomNode(nodel[node].node1);
	if (!R_Cull2DBox(nodel[node].x2lower, nodel[node].y2lower, nodel[node].x2upper, nodel[node].y2upper)||1)
		GLR_RecursiveDoomNode(nodel[node].node2);
}

void GLR_DoomWorld(void)
{
	int texnum;
	gldoomtexture_t *t;
	if (!nodel || !nodec)
		return;	//err... buggy

	for (texnum = 0; texnum < numgldoomtextures; texnum++)	//a hash table might be a good plan.
	{
		t = &gldoomtextures[texnum];
		t->mesh.numindexes = 0;
		t->mesh.numvertexes = 0;
	}
	r_visframecount++;
	GLR_RecursiveDoomNode(nodec-1);

	memset(cl.worldmodel->batches, 0, sizeof(cl.worldmodel->batches));
	for (texnum = 0; texnum < numgldoomtextures; texnum++)	//a hash table might be a good plan.
	{
		t = &gldoomtextures[texnum];
		if (t->mesh.numindexes)
		{
			t->batch.next = cl.worldmodel->batches[t->shader->sort];
			cl.worldmodel->batches[t->shader->sort] = &t->batch;
		}
	}
}
#endif


//find the first ssector, go through it's list/
//grab the lines into multiple arrays.
//make sure all arrays are looped fully. If not, error out.
//if we have two arrays, we have a hole in the middle.
//with multiple arrays, from the second onwards
//	grab two adjacent verts and find the nearest point in any other array, that is also on the positive side.
//	One of the two should be an extreeme, and the external point should be in the direction that the angle points at.
//		none found = error
//	create a triangle from these points, fix array links.
//	move on to next spare array.
//we now have a concave polygon with no holes.
//pick a point, follow along the walls making a triangle fan, until an angle of > 180, throw out fan, rebuild arrays.
//at new point, start a new fan. Be prepared to not be able to generate one.

#define MAX_REGIONS		256
#define MAX_POLYVERTS	(MAX_FLATTRIS*3)
#define MAX_FLATTRIS	1024

//buffer to hold tris
static unsigned short indexes[MAX_POLYVERTS];
static unsigned int numindexes;

typedef struct {
	int vertex[MAX_POLYVERTS];
	unsigned int numverts;
	float angle;
} conectedregion_t;
static conectedregion_t polyregions[MAX_REGIONS];	//we need to be able to join them as we go.
static unsigned int regions;

//throw out duplicates.
static void Triangulate_AddLine(int v1, int v2)	//order makes a difference
{
	int r, v;
	int beginingof = -1;
	int endof = -1;
	int freer = -1;

	for (r = 0; r < regions; r++)
	{
		if (!polyregions[r].numverts)
		{
			freer = r;
			continue;
		}
		if (polyregions[r].vertex[0] == v2)
			beginingof = r;
		if (polyregions[r].vertex[polyregions[r].numverts-1] == v1)
			endof = r;

		for (v = polyregions[r].numverts-2; v >= 0; v--)
			if (polyregions[r].vertex[v] == v1 && polyregions[r].vertex[v+1] == v2)
				return;	//whoops. Duplicate line.
	}
	if (beginingof >= 0 && endof >= 0)
	{	//merge two regions. Copy one onto the end of the other.
		if (beginingof == endof)
		{	//close up
			if (polyregions[endof].numverts+1 >= MAX_POLYVERTS)
			{
				Con_Printf(CON_WARNING "WARNING: Map region is too large.\n");
				return;
			}
			polyregions[endof].vertex[polyregions[endof].numverts] = v2;
			polyregions[endof].numverts++;
		}
		else
		{
			if (polyregions[endof].numverts+polyregions[beginingof].numverts >= MAX_POLYVERTS)
			{
				Con_Printf(CON_WARNING "WARNING: Map region is too large.\n");
				return;
			}
			memcpy(polyregions[endof].vertex + polyregions[endof].numverts,
				polyregions[beginingof].vertex,
				sizeof(polyregions[beginingof].vertex[0])*polyregions[beginingof].numverts);
			polyregions[endof].numverts += polyregions[beginingof].numverts;
			polyregions[beginingof].numverts = 0;
		}
	}
	else if (beginingof >= 0)
	{	//insert into
		if (polyregions[beginingof].numverts+1 >= MAX_POLYVERTS)
		{
			Con_Printf(CON_WARNING "WARNING: Map region is too large.\n");
			return;
		}

		memmove(polyregions[beginingof].vertex + 1,
			polyregions[beginingof].vertex,
			sizeof(polyregions[beginingof].vertex[0])*polyregions[beginingof].numverts);
		polyregions[beginingof].vertex[0] = v1;
		polyregions[beginingof].numverts++;
	}
	else if (endof >= 0)
	{	//stick outselves on the end
		if (polyregions[endof].numverts+1 >= MAX_POLYVERTS)
		{
			Con_Printf(CON_WARNING "WARNING: Map region is too large.\n");
			return;
		}
		polyregions[endof].vertex[polyregions[endof].numverts] = v2;
		polyregions[endof].numverts++;
	}
	else
	{	//new region.
		if (freer < 0)
		{
			freer = regions++;
			if (regions > MAX_REGIONS)
			{
				Con_Printf(CON_WARNING "WARNING: Too many regions. Sector is too chaotic/complicated.\n");
				freer = 0;
				regions = 1;
			}
		}

		polyregions[freer].numverts = 2;
		polyregions[freer].vertex[0] = v1;
		polyregions[freer].vertex[1] = v2;
	}
}

static unsigned short *Triangulate_Finish(int *numtris, unsigned short *old, int oldindexcount)
{
	unsigned short *out;
	unsigned int v1, v2, v3, v;
	unsigned int r, v2s, f;
	float a1;
	float a2;
	for (r = 0; r < regions; r++)
	{
		if (!polyregions[r].numverts)
			continue;

		if (polyregions[r].vertex[0] != polyregions[r].vertex[polyregions[r].numverts-1])
		{
			Con_Printf("Sector is not enclosed\n");
			polyregions[r].vertex[polyregions[r].numverts] = polyregions[r].vertex[0];
			polyregions[r].numverts++;

			/*
			*numtris = 0;
			regions = 0;


			return NULL;*/
		}

		polyregions[r].angle = 0;
		polyregions[r].numverts--;//start == end
		for (v = 0; v < polyregions[r].numverts; v++)
		{
			v1 = polyregions[r].vertex[v];
			v2 = polyregions[r].vertex[(v+1)%(polyregions[r].numverts)];
			v3 = polyregions[r].vertex[(v+2)%(polyregions[r].numverts)];
			a1 = atan2(vertexesl[v3].ypos - vertexesl[v2].ypos, vertexesl[v3].xpos - vertexesl[v2].xpos);
			a2 = atan2(vertexesl[v1].ypos - vertexesl[v2].ypos, vertexesl[v1].xpos - vertexesl[v2].xpos);
			polyregions[r].angle += fabs(a1 - a2);
		}
	}

	//FIXME: inner loops should find the nearest point in a forwards direction from one of the extreeme points.

	//angle should be either (numverts-2)*PI	//inner loop
	//or PI*numverts+2*PI						//outer loop
	//unfortuantly it's rarly either of them...

	for (r = 0; r < regions; r++)
	{
		if (polyregions[r].numverts<3)
			continue;
		v1 = polyregions[r].vertex[0];
		v2 = polyregions[r].vertex[1];
		v2s = 1;
		f=0;
		for (v = 2; polyregions[r].numverts>=3; )
		{	//build a triangle fan.
			if (numindexes+3 > MAX_POLYVERTS)
			{
				Con_Printf(CON_WARNING "WARNING: Sector is too big for triangulation\n");
				break;
			}
			v3 = polyregions[r].vertex[v];

			a1 = atan2(vertexesl[v3].ypos - vertexesl[v2].ypos, vertexesl[v3].xpos - vertexesl[v2].xpos);
			a2 = atan2(vertexesl[v1].ypos - vertexesl[v2].ypos, vertexesl[v1].xpos - vertexesl[v2].xpos);
			if (fabs(a1-a2) > M_PI+0.01)	//this would be a reflex angle then.;.
			{
/*				indexes[numindexes++] = 0;
				indexes[numindexes++] = v2;
				indexes[numindexes++] = 1;
*/
				v1 = v2;
				v2 = v3;
				v2s = v;
				v=(v+1)%polyregions[r].numverts;
				f++;
				if (f >= 1000)
				{	//infinate loop - shouldn't happen. must have got the angle stuff wrong.
					Con_Printf(CON_WARNING "WARNING: Failed to triangulate polygon\n");
					break;
				}
				continue;
			}

			//FIXME: make sure v1 -> v3 doesn't clip any same-region lines.

			indexes[numindexes++] = v1;
			indexes[numindexes++] = v2;
			indexes[numindexes++] = v3;
			memmove(polyregions[r].vertex+v2s, polyregions[r].vertex+v2s+1, (polyregions[r].numverts-v2s)*sizeof(polyregions[r].vertex[0]));
			polyregions[r].numverts--;
			v=(v)%polyregions[r].numverts;
			v2 = v3;
			v2s = v;
			polyregions[r].vertex[polyregions[r].numverts] = 0;
		}
	}

	if (!numindexes)
	{
		Con_Printf(CON_WARNING "Warning: Sector is empty\n");

		*numtris = 0;
		regions = 0;

		return NULL;
	}

	out = BZ_Realloc(old, sizeof(*out)*(numindexes+oldindexcount*3));
	memcpy(out+oldindexcount*3, indexes, sizeof(*out)*numindexes);

	*numtris = numindexes/3+oldindexcount;
	regions = 0;
	numindexes = 0;

	return out;
}

static void Triangulate_Sectors(dsector_t *sectorl, qboolean glbspinuse)
{
	int seg, nsec;
	int i, sec=-1;

	sectorm = Z_Malloc(sectorc * sizeof(*sectorm));

	if (glbspinuse)
	{
		for (i = 0; i < ssectorsc; i++)
		{	//only do linedefs.
			for (seg = ssectorsl[i].first; seg < ssectorsl[i].first + ssectorsl[i].segcount; seg++)
				if (segsl[seg].linedef != 0xffff)
					break;

			if (seg == ssectorsl[i].first + ssectorsl[i].segcount)	//throw a fit.
			{
				Con_Printf("SubSector %i has absolutly no walls\n", i);
				continue;
			}
				
			nsec = sidedefsm[linedefsl[segsl[seg].linedef].sidedef[segsl[seg].direction]].sector;
			if (sec != nsec)
			{
				if (sec>=0)
					sectorm[sec].flats = Triangulate_Finish(&sectorm[sec].numflattris, sectorm[sec].flats, sectorm[sec].numflattris);
				sec = nsec;
			}
			for (seg = ssectorsl[i].first; seg < ssectorsl[i].first + ssectorsl[i].segcount; seg++)
			{	//ignore direction, it's do do with the intersection rather than the draw direction.
				Triangulate_AddLine(segsl[seg].vert[0], segsl[seg].vert[1]);
			}
		}
		if (sec>=0)
			sectorm[sec].flats = Triangulate_Finish(&sectorm[sec].numflattris, sectorm[sec].flats, sectorm[sec].numflattris);
	}
	else
	{
		for (sec = 0; sec < sectorc; sec++)
		{
			for (i = 0; i < linedefsc; i++)
			{
				if (sidedefsm[linedefsl[i].sidedef[0]].sector == sec)
					Triangulate_AddLine(linedefsl[i].vert[0], linedefsl[i].vert[1]);
				if (linedefsl[i].sidedef[1] != 0xffff && sidedefsm[linedefsl[i].sidedef[1]].sector == sec)
					Triangulate_AddLine(linedefsl[i].vert[1], linedefsl[i].vert[0]);
			}
			sectorm[sec].flats = Triangulate_Finish(&sectorm[sec].numflattris, sectorm[sec].flats, sectorm[sec].numflattris);
		}
	}

	/*
	for (i = 0; i < ssectorsc; i++)
	{	//only do linedefs.
		seg = ssectorsl[i].first;
		nsec = sidedefsm[linedefsl[segsl[seg].linedef].sidedef[segsl[seg].direction]].sector;
		if (sec != nsec)
		{
			if (sec>=0)
				sectorm[sec].flats = Triangulate_Finish(&sectorm[sec].numflattris);
			sec = nsec;
		}
		for (seg = ssectorsl[i].first; seg < ssectorsl[i].first + ssectorsl[i].segcount; seg++)
		{	//ignore direction, it's do do with the intersection rather than the draw direction.
			Triangulate_AddLine(segsl[seg].vert[0], segsl[seg].vert[1]);
		}
	}
	if (sec>=0)
		sectorm[sec].flats = Triangulate_Finish(&sectorm[sec].numflattris);
	*/

	for (i = 0; i < sectorc; i++)
	{
		sectorm[i].ceilingtex = Doom_LoadFlat(sectorl[i].ceilingtexture);
		sectorm[i].floortex = Doom_LoadFlat(sectorl[i].floortexture);
		sectorm[i].lightlev = sectorl[i].lightlevel;
		sectorm[i].specialtype = sectorl[i].specialtype;
		sectorm[i].tag = sectorl[i].tag;
		sectorm[i].ceilingheight = sectorl[i].ceilingheight;
		sectorm[i].floorheight = sectorl[i].floorheight;
	}
}

#ifndef SERVERONLY
static void *textures1;
static void *textures2;
static char *pnames;
static void Doom_LoadTextureInfos(void)
{
	textures1 = FS_LoadMallocFile("wad/texture1");
	textures2 = FS_LoadMallocFile("wad/texture2");
	pnames = FS_LoadMallocFile("wad/pnames");
}

typedef struct {
	char name[8];
	short always0_0;
	short always0_1;
	short width;
	short height;
	short always0_2;
	short always0_3;
	short componantcount;
} ddoomtexture_t;
typedef struct {
	short xoffset;
	short yoffset;
	unsigned short patchnum;
	unsigned short always_1;
	unsigned short always_0;
} ddoomtexturecomponant_t;

typedef struct {
	short width;
	short height;
	short xpos;
	short ypos;
} doomimage_t;

static void Doom_ExtractPName(unsigned int *out, doomimage_t *di, int outwidth, int outheight, int x, int y)
{
	unsigned int *colpointers;
	int c, fr, rc, extra;
	unsigned char *data, *coldata;
	extern qbyte		gammatable[256];

	if (!di)
		return;

	data = (char *)di;


//	out += x/*+di->xpos*/;
//	out += (y/*+di->ypos*/)*outwidth;

	colpointers = (unsigned int*)(data+sizeof(doomimage_t));
	for (c = 0; c < di->width; c++)
	{
		if (c+x < 0)
			continue;
		if (c+x >= outwidth)
			break;

		if (colpointers[c] >= com_filesize)
			break;
		coldata = data + colpointers[c];
		while(1)
		{
			fr = *coldata++;
			if (fr == 255)
				break;

			rc = *coldata++;

			coldata++;	//one not drawn, on each side

			fr+=y;

			if (fr<0)
			{
				coldata -= fr;	//plus
				fr = 0;
			}

			if ((fr+rc) > outheight)
			{
				extra = rc - (outheight - fr) +1;
				rc = outheight - fr;
				if (rc < 0)
					break;
			}
			else
				extra = 1;

			while(rc)
			{
				out[c+x + fr*outwidth] = (gammatable[doompalette[*coldata*3]]) + (gammatable[doompalette[*coldata*3+1]]<<8) + (gammatable[doompalette[*coldata*3+2]]<<16) + (255<<24);
				coldata++;
				fr++;
				rc--;
			}

			coldata+=extra; //one not drawn, on each side
		}
	}
}

static texid_t Doom_LoadPatchFromTexWad(char *name, void *texlump, unsigned short *width, unsigned short *height, qboolean *hasalpha)
{
	char patch[32] = "patches/";
	unsigned int *tex;
	ddoomtexture_t *tx;
	ddoomtexturecomponant_t *tc;
	texid_t result;
	int i;
	int count;

	count = *(int *)texlump;
	tex = (int *)texlump+1;

	for (i = 0; i < count; i++)
	{
		tx = (ddoomtexture_t*)((unsigned char*)texlump + *tex);
		if (!strncmp(tx->name, name, 8))
		{
			tex = BZ_Malloc(tx->width*tx->height*4);
			memset(tex, 0, tx->width*tx->height*4);
			*width = tx->width;
			*height = tx->height;
			tc = (ddoomtexturecomponant_t*)(tx+1);
			for (i = 0; i < tx->componantcount; i++, tc++)
			{
				strncpy(patch+8, pnames+4+8*tc->patchnum, 8);
				Q_strlwr(patch+8);
				patch[16] = '\0';

				Doom_ExtractPName(tex, (doomimage_t *)COM_LoadTempFile(patch), tx->width, tx->height, tc->xoffset, tc->yoffset);
			}

			*hasalpha = false;
			for (i = 0; i < tx->width * tx->height; i++)
			{
				if (!(tex[i] & 0xff000000))
				{
					*hasalpha = true;
					break;
				}
			}

			result = R_LoadTexture32(name, tx->width, tx->height, tex, 0);
			BZ_Free(tex);
			return result;
		}

		tex++;
	}

	return r_nulltex;
}
static int Doom_LoadPatch(char *name)
{
	texid_t tex;
	qboolean hasalpha = false;
	int texnum;

	for (texnum = 0; texnum < numgldoomtextures; texnum++)	//a hash table might be a good plan.
	{
		if(!strncmp(name, gldoomtextures[texnum].name, 8))
		{
			return texnum;
		}
	}
	//couldn't find it.
//	texnum = numgldoomtextures;

	gldoomtextures = BZ_Realloc(gldoomtextures, sizeof(*gldoomtextures)*((numgldoomtextures+16)&~15));
	memset(gldoomtextures + numgldoomtextures, 0, sizeof(gldoomtextures[numgldoomtextures]));
	numgldoomtextures++;

	strncpy(gldoomtextures[texnum].name, name, 8);

	tex = r_nulltex;
	if (textures1 && !TEXVALID(tex))
		tex = Doom_LoadPatchFromTexWad(name, textures1, &gldoomtextures[texnum].width, &gldoomtextures[texnum].height, &hasalpha);
	if (textures2 && !TEXVALID(tex))
		tex = Doom_LoadPatchFromTexWad(name, textures2, &gldoomtextures[texnum].width, &gldoomtextures[texnum].height, &hasalpha);
	if (!TEXVALID(tex))
	{
		//all else failed.
		gldoomtextures[texnum].width = image_width;
		gldoomtextures[texnum].height = image_height;
		gldoomtextures[texnum].meshptr = &gldoomtextures[texnum].mesh;
		gldoomtextures[texnum].batch.mesh = &gldoomtextures[texnum].meshptr;
		gldoomtextures[texnum].batch.next = loadmodel->batches[gldoomtextures[texnum].shader->sort];
		loadmodel->batches[gldoomtextures[texnum].shader->sort] = &gldoomtextures[texnum].batch;
	}

	if (hasalpha)
		gldoomtextures[texnum].shader = R_RegisterShader(name, "{\n{\nmap $diffuse\nrgbgen vertex\nalphagen vertex\nalphafunc ge128\n}\n}\n");
	else
		gldoomtextures[texnum].shader = R_RegisterShader(name, "{\n{\nmap $diffuse\nrgbgen vertex\nalphagen vertex\n}\n}\n");
	gldoomtextures[texnum].shader->defaulttextures.base = tex;

	return texnum;
}
static void Doom_Purge (struct model_s *mod)
{
	int texnum;
	for (texnum = 0; texnum < numgldoomtextures; texnum++)
	{
		BZ_Free(gldoomtextures[texnum].mesh.colors4b_array);
		BZ_Free(gldoomtextures[texnum].mesh.st_array);
		BZ_Free(gldoomtextures[texnum].mesh.xyz_array);
		BZ_Free(gldoomtextures[texnum].mesh.indexes);
	}
	BZ_Free(gldoomtextures);
	gldoomtextures = NULL;
}
#endif
static void CleanWalls(dsidedef_t *sidedefsl)
{
	int i;
	char texname[64];
	char lastmiddle[9]="-";
	char lastlower[9]="-";
	char lastupper[9]="-";
	int lastmidtex=0, lastuptex=0, lastlowtex=0;
	sidedefsm = BZ_Malloc(sidedefsc * sizeof(*sidedefsm));
	for (i = 0; i < sidedefsc; i++)
	{
#ifdef GLQUAKE
		strncpy(texname, sidedefsl[i].middletex, 8);
		texname[8] = '\0';
		if (!strcmp(texname, "-"))
			sidedefsm[i].middletex = 0;
		else
		{
			if (!strncmp(texname, lastmiddle, 8))
				sidedefsm[i].middletex = lastmidtex;
			else
			{
				strncpy(lastmiddle, texname, 8);
				sidedefsm[i].middletex = lastmidtex = Doom_LoadPatch(texname);//Mod_LoadHiResTexture(texname, true, false); 
			}
		}

		strncpy(texname, sidedefsl[i].lowertex, 8);
		texname[8] = '\0';
		if (!strcmp(texname, "-"))
			sidedefsm[i].lowertex = 0;
		else
		{
			if (!strncmp(texname, lastlower, 8))
				sidedefsm[i].lowertex = lastlowtex;
			else
			{
				strncpy(lastlower, texname, 8);
				sidedefsm[i].lowertex = lastlowtex = Doom_LoadPatch(texname);//Mod_LoadHiResTexture(texname, true, true); 
			}
		}

		strncpy(texname, sidedefsl[i].uppertex, 8);
		texname[8] = '\0';
		if (!strcmp(texname, "-"))
			sidedefsm[i].uppertex = 0;
		else
		{
			if (!strncmp(texname, lastupper, 8))
				sidedefsm[i].uppertex = lastuptex;
			else
			{
				strncpy(lastupper, texname, 8);
				sidedefsm[i].uppertex = lastuptex = Doom_LoadPatch(texname);//Mod_LoadHiResTexture(texname, true, false); 
			}
		}
#endif
		sidedefsm[i].sector = sidedefsl[i].sector;
		sidedefsm[i].texx = sidedefsl[i].texx;
		sidedefsm[i].texy = sidedefsl[i].texy;
	}
}

void QuakifyThings(dthing_t *thingsl)
{
	int sector;
	int spawnflags;
	char *name;
	int i;
	int zpos;
	static char newlump[1024*1024];
	char *ptr = newlump;
	vec3_t point;

	sprintf(ptr,	"{\n"
					"\"classname\" \"worldspawn\"\n"
					"}\n");
	ptr += strlen(ptr);

	for (i = 0; i < thingsc; i++)
	{
		switch(thingsl[i].type)
		{
		case THING_PLAYER:	//fixme: spit out a coop spawn too.
			name = "info_player_start";
			break;
		case THING_PLAYER2:
		case THING_PLAYER3:
		case THING_PLAYER4:
			name = "info_player_coop";
			break;
		case THING_DMSPAWN:
			name = "info_player_deathmatch";
			break;


		case THING_WCHAINSAW:
			name = "item_artifact_super_damage";
			break;
		case THING_WSHOTGUN1:
			name = "weapon_nailgun";
			break;
		case THING_WSHOTGUN2:
			name = "weapon_supernailgun";
			break;
		case THING_WCHAINGUN:
			name = "weapon_supershotgun";
			break;
		case THING_WROCKETL:
			name = "weapon_rocketlauncher";
			break;
		case THING_WPLASMA:
			name = "weapon_grenadelauncher";
			break;
		case THING_WBFG:
			name = "weapon_lightning";
			break;

		default:
			name = va("thing_%i", thingsl[i].type);
			break;
		}

		point[0] = thingsl[i].xpos;
		point[1] = thingsl[i].ypos;
		point[2] = 0;
		sector = Doom_SectorNearPoint(point);
		zpos = sectorm[sector].floorheight + 24;	//things have no z coord, so find the sector they're in

		spawnflags = SPAWNFLAG_NOT_EASY | SPAWNFLAG_NOT_MEDIUM | SPAWNFLAG_NOT_HARD | SPAWNFLAG_NOT_DEATHMATCH;
		if (thingsl[i].flags & THING_EASY)
			spawnflags -= SPAWNFLAG_NOT_EASY;
		if (thingsl[i].flags & THING_MEDIUM)
			spawnflags -= SPAWNFLAG_NOT_MEDIUM;
		if (thingsl[i].flags & THING_HARD)
			spawnflags -= SPAWNFLAG_NOT_HARD;
		if (thingsl[i].flags & THING_DEATHMATCH)
			spawnflags -= SPAWNFLAG_NOT_DEATHMATCH;
		if (thingsl[i].flags & THING_DEAF)
			spawnflags |= 1;

		sprintf(ptr,	"{\n"
						"\"classname\" \"%s\"\n"
						"\"origin\" \"%i %i %i\"\n"
						"\"spawnflags\" \"%i\"\n"
						"\"angle\" \"%i\"\n"
						"}\n",
							name,
							thingsl[i].xpos, thingsl[i].ypos, zpos,
							spawnflags,
							thingsl[i].angle
						);
		ptr += strlen(ptr);
	}

	loadmodel->entities = BZ_Malloc(ptr-newlump+1);
	memcpy(loadmodel->entities, newlump, ptr-newlump+1);
}

void Doom_GeneratePlanes(ddoomnode_t *nodel)
{
	vec3_t point, up, line;
	int n;
	up[0] = 0;
	up[1] = 0;
	up[2] = 1;
	line[2] = 0;
	nodeplanes = BZ_Malloc(sizeof(*nodeplanes)*nodec);
	lineplanes = BZ_Malloc(sizeof(*lineplanes)*linedefsc);
	point[2] = 0;
	for (n = 0; n < nodec; n++)
	{
		line[0] = nodel[n].dx;
		line[1] = nodel[n].dy;
		point[0] = nodel[n].x;
		point[1] = nodel[n].y;
		CrossProduct(line, up, nodeplanes[n].normal);
		VectorNormalize(nodeplanes[n].normal);
		nodeplanes[n].dist = DotProduct (point, nodeplanes[n].normal);
	}

	for (n = 0; n < linedefsc; n++)
	{
		point[0] = vertexesl[linedefsl[n].vert[0]].xpos;
		point[1] = vertexesl[linedefsl[n].vert[0]].ypos;
		line[0] = vertexesl[linedefsl[n].vert[1]].xpos-point[0];
		line[1] = vertexesl[linedefsl[n].vert[1]].ypos-point[1];
		CrossProduct(line, up, lineplanes[n].normal);
		VectorNormalize(lineplanes[n].normal);
		lineplanes[n].dist = DotProduct (point, lineplanes[n].normal);
	}
}

/*
doom maps have no network limitations, but has +/-32767 map size limits (same as quake bsp)
fte defaults to a +/- 4096 world
a lot of maps are off-centered and can be moved to get them to fit fte's constraints, so if we can, do so
*/
static void MoveWorld(void)
{
	int v;
	short adj[2];
	short min[2], max[2];
	min[0] = 4096;
	min[1] = 4096;
	max[0] = -4096;
	max[1] = -4096;

	for (v = 0; v < vertexesc; v++)
	{
		if (min[0] > vertexesl[v].xpos)
			min[0] = vertexesl[v].xpos;
		if (min[1] > vertexesl[v].ypos)
			min[1] = vertexesl[v].ypos;

		if (max[0] < vertexesl[v].xpos)
			max[0] = vertexesl[v].xpos;
		if (max[1] < vertexesl[v].ypos)
			max[1] = vertexesl[v].ypos;
	}

	if (min[0]>=-4096 && max[0]<=4096)
		if (min[1]>=-4096 && max[1]<=4096)
			return;	//doesn't need adjusting, live with it.

	if (max[0]-min[0]>=8192 || max[1]-min[1]>=8192)
	{
		Con_Printf(CON_WARNING "Warning: Map is too large for the network protocol\n");
		return;
	}

	adj[0] = (max[0]-4096)&~63;	//don't harm the tiling.
	adj[1] = (max[1]-4096)&~63;

	Con_Printf("Adjusting map (%i %i)\n", -adj[0], -adj[1]);

	for (v = 0; v < vertexesc; v++)
	{
		vertexesl[v].xpos -= adj[0];
		vertexesl[v].ypos -= adj[1];
	}

	for (v = 0; v < nodec; v++)
	{
		nodel[v].x -= adj[0];
		nodel[v].y -= adj[1];

		nodel[v].x1lower -= adj[0];
		nodel[v].x1upper -= adj[1];
		nodel[v].y1lower -= adj[0];
		nodel[v].y1upper -= adj[1];

		nodel[v].x2lower -= adj[0];
		nodel[v].x2upper -= adj[1];
		nodel[v].y2lower -= adj[0];
		nodel[v].y2upper -= adj[1];
	}

	for (v = 0; v < thingsc; v++)
	{
		thingsl[v].xpos -= adj[0];
		thingsl[v].ypos -= adj[1];
	}

	blockmapl->xorg -= adj[0];
	blockmapl->yorg -= adj[1];
}


static void Doom_LoadVerticies(char *name)
{
	ddoomvertex_t *std, *gl1;
	int stdc, glc;
	int *gl2;
	int i;

	std		= (void *)COM_LoadTempFile	(va("%s.vertexes",	name));
	stdc	= com_filesize/sizeof(*std);

	gl2		= (void *)COM_LoadTempMoreFile	(va("%s.gl_vert",	name));
	if (!gl2)
	{
		glc = 0;
		gl1 = NULL;
	}
	else if (gl2[0] == *(int*)"gNd2")
	{
		gl2++;
		glc = (com_filesize-4)/sizeof(int)/2;
		gl1 = NULL;
	}
	else
	{
		glc	= com_filesize/sizeof(*gl1);
		gl1 = (ddoomvertex_t*)gl2;
	}

	if (!stdc)
		return;

	vertexesc = stdc + glc;
	vertexesl = BZ_Malloc(vertexesc*sizeof(*vertexesl));

	vertexsglbase = stdc;

	for (i = 0; i < stdc; i++)
	{
		vertexesl[i].xpos = std[i].xpos;
		vertexesl[i].ypos = std[i].ypos;
	}
	if (gl1)
	{
		for (i = 0; i < glc; i++)
		{
			vertexesl[stdc+i].xpos = gl1[i].xpos;
			vertexesl[stdc+i].ypos = gl1[i].ypos;
		}
	}
	else
	{
		for (i = 0; i < glc; i++)
		{
			vertexesl[stdc+i].xpos = (float)gl2[i*2] / 0x10000;
			vertexesl[stdc+i].ypos = (float)gl2[i*2+1] / 0x10000;
		}
	}
}

static void Doom_LoadSSectors(char *name)
{
	ssectorsl	= (void *)FS_LoadMallocFile	(va("%s.gl_ssect",	name));
	if (!ssectorsl)
		ssectorsl	= (void *)FS_LoadMallocFile	(va("%s.ssectors",	name));
	//FIXME: "gNd3" means that it's glbsp version 3.
	ssectorsc	= com_filesize/sizeof(*ssectorsl);
}

static void Doom_LoadSSegs(char *name)
{	//these skirt the subsectors

	void *file;
	dgl_seg3_t	*s3;
	dgl_seg1_t	*s1;
	dseg_t		*s0;
	int i;

	file	= (void *)FS_LoadMallocFile	(va("%s.gl_segs",	name));
	if (!file)
	{
		s0 = (void *)FS_LoadMallocFile	(va("%s.segs",	name));
		segsc	= com_filesize/sizeof(*s0);

		segsl = BZ_Malloc(segsc * sizeof(*segsl));
		for (i = 0; i < segsc; i++)
		{
			segsl[i].vert[0] = s0[i].vert[0];
			segsl[i].vert[1] = s0[i].vert[1];
			segsl[i].linedef = s0[i].linedef;
			segsl[i].direction = s0[i].direction;
			segsl[i].Partner = 0xffff;
		}
	}
	else if (*(int *)file == *(int *)"gNd3")
	{
		s3 = file;
		segsc	= com_filesize/sizeof(*s3);

		segsl = s3;
	}
	else if (!file)
		return;
	else
	{
		s1 = file;
		segsc	= com_filesize/sizeof(*s1);

		segsl = BZ_Malloc(segsc * sizeof(*segsl));
		for (i = 0; i < segsc; i++)
		{
			if (s1[i].vert[0] & 0x8000)
				segsl[i].vert[0] = (s1[i].vert[0]&0x7fff)+vertexsglbase;
			else
				segsl[i].vert[0] = s1[i].vert[0];
			if (s1[i].vert[1] & 0x8000)
				segsl[i].vert[1] = (s1[i].vert[1]&0x7fff)+vertexsglbase;
			else
				segsl[i].vert[1] = s1[i].vert[1];
			segsl[i].linedef = s1[i].linedef;
			segsl[i].direction = s1[i].direction;
			if (s1[i].Partner == 0xffff)
				segsl[i].Partner = 0xffffffff;
			else
				segsl[i].Partner = s1[i].Partner;
		}
	}
}

qboolean Mod_LoadDoomLevel(model_t *mod)
{
	int h;
	dsector_t		*sectorl;
	dsidedef_t		*sidedefsl;
	char name[MAX_QPATH];

	int *gl_nodes;

	COM_StripExtension(mod->name, name, sizeof(name));

	if (!COM_LoadTempFile(va("%s", mod->name)))
	{
		Con_Printf("Wad map %s does not exist\n", mod->name);
		return false;
	}

	gl_nodes	= (void *)FS_LoadMallocFile	(va("%s.gl_nodes",	name));
	if (gl_nodes && com_filesize>0)
	{
		nodel = (void *)gl_nodes;
		nodec = com_filesize/sizeof(*nodel);
	}
	else
	{
		gl_nodes=NULL;
		nodel		= (void *)FS_LoadMallocFile	(va("%s.nodes",		name));
		nodec		= com_filesize/sizeof(*nodel);
	}
	sectorl		= (void *)FS_LoadMallocFile	(va("%s.sectors",	name));
	sectorc		= com_filesize/sizeof(*sectorl);

#ifndef SERVERONLY
	numgldoomtextures=0;
	Doom_LoadPalette();
#endif


	Doom_LoadVerticies(name);

	Doom_LoadSSegs(name);
	Doom_LoadSSectors(name);

	thingsl		= (void *)FS_LoadMallocFile	(va("%s.things",	name));
	thingsc		= com_filesize/sizeof(*thingsl);
	linedefsl	= (void *)FS_LoadMallocFile	(va("%s.linedefs",	name));
	linedefsc	= com_filesize/sizeof(*linedefsl);
	sidedefsl	= (void *)FS_LoadMallocFile	(va("%s.sidedefs",	name));
	sidedefsc	= com_filesize/sizeof(*sidedefsl);
	blockmapl	= (void *)FS_LoadMallocFile	(va("%s.blockmap",	name));
//	blockmaps	= com_filesize;
#ifndef SERVERONLY
	Doom_LoadTextureInfos();
#endif
	blockmapofs = (unsigned short*)(blockmapl+1);

	if (!nodel || !sectorl || !segsl || !ssectorsl || !thingsl || !linedefsl || !sidedefsl || !vertexesl)
	{
		Sys_Error("Wad map doesn't contain enough lumps\n");
		nodel = NULL;
		return false;
	}

	MoveWorld();

	Doom_GeneratePlanes(nodel);

	mod->hulls[0].clip_mins[0] = 0;
	mod->hulls[0].clip_mins[1] = 0;
	mod->hulls[0].clip_mins[2] = 0;
	mod->hulls[0].clip_maxs[0] = 0;
	mod->hulls[0].clip_maxs[1] = 0;
	mod->hulls[0].clip_maxs[2] = 0;
	mod->hulls[0].available = true;

	for (h = 1; h < MAX_MAP_HULLSM; h++)
		mod->hulls[h].available = false;

	Doom_SetModelFunc(mod);

	mod->needload = false;
	mod->fromgame = fg_doom;
	mod->type = mod_brush;
	mod->nodes = (void*)0x1;

	CleanWalls(sidedefsl);

	Triangulate_Sectors(sectorl, !!gl_nodes);

	QuakifyThings(thingsl);

	return true;
}

void Doom_LightPointValues(model_t *model, vec3_t point, vec3_t res_diffuse, vec3_t res_ambient, vec3_t res_dir)
{
	msector_t *sec;
	sec = sectorm + Doom_SectorNearPoint(point);

	res_dir[0] = 0;
	res_dir[1] = 1;
	res_dir[2] = 1;
	res_diffuse[0] = sec->lightlev;
	res_diffuse[1] = sec->lightlev;
	res_diffuse[2] = sec->lightlev;
	res_ambient[0] = sec->lightlev;
	res_ambient[1] = sec->lightlev;
	res_ambient[2] = sec->lightlev;
}

//return pvs bits for point
unsigned int Doom_FatPVS(struct model_s *model, vec3_t org, qbyte *pvsbuffer, unsigned int buffersize, qboolean merge)
{
	//FIXME: use REJECT lump.
	return 0;
}

//check if an ent is within the given pvs
qboolean Doom_EdictInFatPVS(struct model_s *model, struct pvscache_s *edict, qbyte *pvsbuffer)
{	//FIXME: use REJECT lump.
	return true;
}

//generate useful info for correct functioning of Doom_EdictInFatPVS.
void Doom_FindTouchedLeafs(struct model_s *model, struct pvscache_s *ent, vec3_t cullmins, vec3_t cullmaxs)
{
	//work out the sectors this ent is in for easy pvs.
}

//requires lightmaps - not supported.
void Doom_StainNode(struct mnode_s *node, float *parms)
{
}

//requires lightmaps - not supported.
void Doom_MarkLights(struct dlight_s *light, int bit, struct mnode_s *node)
{
}

void Doom_SetModelFunc(model_t *mod)
{
#ifndef SERVERONLY
	mod->funcs.PurgeModel			= Doom_Purge;
#endif
	mod->funcs.FatPVS				= Doom_FatPVS;
	mod->funcs.EdictInFatPVS		= Doom_EdictInFatPVS;
	mod->funcs.FindTouchedLeafs		= Doom_FindTouchedLeafs;

	mod->funcs.LightPointValues		= Doom_LightPointValues;
	mod->funcs.StainNode			= Doom_StainNode;
	mod->funcs.MarkLights			= Doom_MarkLights;

//	mod->funcs.LeafPVS)			(struct model_s *model, int num, qbyte *buffer, unsigned int buffersize);

	mod->funcs.NativeTrace = Doom_Trace;
	mod->funcs.PointContents = Doom_PointContents;

	//Doom_SetCollisionFuncs(mod);
}

#endif