amxmodx/hlsdk/utils/qcsg/brush.c
2006-08-27 02:22:59 +00:00

988 lines
20 KiB
C

/***
*
* Copyright (c) 1996-2002, Valve LLC. All rights reserved.
*
* This product contains software technology licensed from Id
* Software, Inc. ("Id Technology"). Id Technology (c) 1996 Id Software, Inc.
* All Rights Reserved.
*
****/
// brush.c
#include "csg.h"
plane_t mapplanes[MAX_MAP_PLANES];
int nummapplanes;
/*
=============================================================================
PLANE FINDING
=============================================================================
*/
void FindGCD (int *v)
{
int i, j, smallest;
int rem[3];
int val[3];
for (i=0 ; i<3 ; i++)
val[i] = abs(v[i]);
while (1)
{
smallest = 1<<30;
for (i=0 ; i<3 ; i++)
{
j = abs(val[i]);
if (j && j<smallest)
smallest = j;
}
for (i=0 ; i<3 ; i++)
rem[i] = val[i]%smallest;
if (rem[0] + rem[1] + rem[2] == 0)
break; // smallest == gcd
for (i=0 ; i<3 ; i++)
if (!rem[i])
val[i] = smallest;
else
val[i] = rem[i];
}
for (i=0 ; i<3 ; i++)
v[i] /= smallest;
}
int PlaneTypeForNormal (vec3_t normal)
{
vec_t ax, ay, az;
// NOTE: should these have an epsilon around 1.0?
if (normal[0] == 1.0 || normal[0] == -1.0)
return PLANE_X;
if (normal[1] == 1.0 || normal[1] == -1.0)
return PLANE_Y;
if (normal[2] == 1.0 || normal[2] == -1.0)
return PLANE_Z;
ax = fabs(normal[0]);
ay = fabs(normal[1]);
az = fabs(normal[2]);
if (ax >= ay && ax >= az)
return PLANE_ANYX;
if (ay >= ax && ay >= az)
return PLANE_ANYY;
return PLANE_ANYZ;
}
/*
=============
FindIntPlane
Returns which plane number to use for a given integer defined plane.
=============
*/
int FindIntPlane (int *inormal, int *iorigin)
{
int i, j;
plane_t *p, temp;
int t;
vec3_t origin;
qboolean locked;
FindGCD (inormal);
p = mapplanes;
locked = false;
i = 0;
while (1)
{
if (i == nummapplanes)
{
if (!locked)
{
locked = true;
ThreadLock (); // make sure we don't race
}
if (i == nummapplanes)
break; // we didn't race
}
// see if origin is on plane
t = 0;
for (j=0 ; j<3 ; j++)
t += (iorigin[j] - p->iorigin[j]) * inormal[j];
if (!t)
{ // on plane
// see if the normal is forward, backwards, or off
for (j=0 ; j<3 ; j++)
if (inormal[j] != p->inormal[j])
break;
if (j == 3)
{
if (locked)
ThreadUnlock ();
return i;
}
}
i++;
p++;
}
if (!locked)
Error ("not locked");
// create a new plane
for (j=0 ; j<3 ; j++)
{
p->inormal[j] = inormal[j];
(p+1)->inormal[j] = -inormal[j];
p->iorigin[j] = iorigin[j];
(p+1)->iorigin[j] = iorigin[j];
p->normal[j] = inormal[j];
origin[j] = iorigin[j];
}
if (nummapplanes >= MAX_MAP_PLANES)
Error ("MAX_MAP_PLANES");
VectorNormalize (p->normal);
p->type = (p+1)->type = PlaneTypeForNormal (p->normal);
p->dist = DotProduct (origin, p->normal);
VectorSubtract (vec3_origin, p->normal, (p+1)->normal);
(p+1)->dist = -p->dist;
// allways put axial planes facing positive first
if (p->type < 3)
{
if (inormal[0] < 0 || inormal[1] < 0 || inormal[2] < 0)
{
// flip order
temp = *p;
*p = *(p+1);
*(p+1) = temp;
nummapplanes += 2;
ThreadUnlock ();
return i + 1;
}
}
nummapplanes += 2;
ThreadUnlock ();
return i;
}
int PlaneFromPoints (int *p0, int *p1, int *p2)
{
int j;
int t1[3], t2[3];
int normal[3];
// convert to a vector / dist plane
for (j=0 ; j<3 ; j++)
{
t1[j] = p0[j] - p1[j];
t2[j] = p2[j] - p1[j];
}
FindGCD (t1);
FindGCD (t2);
normal[0] = t1[1]*t2[2] - t1[2]*t2[1];
normal[1] = t1[2]*t2[0] - t1[0]*t2[2];
normal[2] = t1[0]*t2[1] - t1[1]*t2[0];
if (!normal[0] && !normal[1] && !normal[2])
return -1;
return FindIntPlane (normal, p0);
}
/*
=============================================================================
TURN BRUSHES INTO GROUPS OF FACES
=============================================================================
*/
void ScaleUpIVector (int *iv, int min)
{
int i;
int largest, scale;
largest = 0;
for (i=0 ; i<3 ; i++)
{
if (abs(iv[i]) > largest)
largest = abs(iv[i]);
}
scale = (min + largest - 1)/largest;
for (i=0 ; i<3 ; i++)
iv[i] *= scale;
}
/*
=================
BaseWindingForIPlane
=================
*/
winding_t *BaseWindingForIPlane (plane_t *p)
{
int i, x;
vec_t max, v;
winding_t *w;
int org[3], vup[3], vright[3];
VectorCopy (p->iorigin, org);
VectorCopy (vec3_origin, vup);
VectorCopy (vec3_origin, vright);
if (!p->inormal[1] && !p->inormal[2])
{
vup[2] = 8192;
vright[1] = 8192*p->normal[0];
}
else if (!p->inormal[0] && !p->inormal[2])
{
vup[2] = 8192;
vright[0] = -8192*p->normal[1];
}
else if (!p->inormal[0] && !p->inormal[1])
{
vup[1] = 8192;
vright[0] = 8192*p->normal[2];
}
else
{
vup[0] = -2*p->inormal[1]*p->inormal[2];
vup[1] = p->inormal[0]*p->inormal[2];
vup[2] = p->inormal[0]*p->inormal[1];
FindGCD (vup);
vright[0] = vup[1]*p->inormal[2] - vup[2]*p->inormal[1];
vright[1] = vup[2]*p->inormal[0] - vup[0]*p->inormal[2];
vright[2] = vup[0]*p->inormal[1] - vup[1]*p->inormal[0];
FindGCD (vright);
ScaleUpIVector (vup, 8192);
ScaleUpIVector (vright, 8192);
}
w = AllocWinding (4);
VectorSubtract (org, vright, w->p[0]);
VectorAdd (w->p[0], vup, w->p[0]);
VectorAdd (org, vright, w->p[1]);
VectorAdd (w->p[1], vup, w->p[1]);
VectorAdd (org, vright, w->p[2]);
VectorSubtract (w->p[2], vup, w->p[2]);
VectorSubtract (org, vright, w->p[3]);
VectorSubtract (w->p[3], vup, w->p[3]);
w->numpoints = 4;
return w;
}
/*
==============================================================================
BEVELED CLIPPING HULL GENERATION
This is done by brute force, and could easily get a lot faster if anyone cares.
==============================================================================
*/
#if 0
vec3_t hull_size[NUM_HULLS][2] = {
{ {0, 0, 0}, {0, 0, 0} },
{ {-16,-16,-32}, {16,16,24} },
{ {-32,-32,-64}, {32,32,24} }
};
#endif
#if 1
vec3_t hull_size[NUM_HULLS][2] = {
{ {0, 0, 0}, {0, 0, 0} },
{ {-16,-16,-36}, {16,16,36} },// 32x32x72
{ {-32,-32,-32}, {32,32,32} }, // 64x64x64
{ {-16,-16,-18}, {16,16,18} } // 32x32x36
};
#endif
#define MAX_HULL_POINTS 32
#define MAX_HULL_EDGES 64
typedef struct
{
brush_t *b;
int hullnum;
int num_hull_points;
vec3_t hull_points[MAX_HULL_POINTS];
vec3_t hull_corners[MAX_HULL_POINTS*8];
int num_hull_edges;
int hull_edges[MAX_HULL_EDGES][2];
} expand_t;
/*
=============
IPlaneEquiv
=============
*/
qboolean IPlaneEquiv (plane_t *p1, plane_t *p2)
{
int t;
int j;
// see if origin is on plane
t = 0;
for (j=0 ; j<3 ; j++)
t += (p2->iorigin[j] - p1->iorigin[j]) * p2->inormal[j];
if (t)
return false;
// see if the normal is forward, backwards, or off
for (j=0 ; j<3 ; j++)
if (p2->inormal[j] != p1->inormal[j])
break;
if (j == 3)
return true;
for (j=0 ; j<3 ; j++)
if (p2->inormal[j] != -p1->inormal[j])
break;
if (j == 3)
return true;
return false;
}
/*
============
AddBrushPlane
=============
*/
void AddBrushPlane (expand_t *ex, plane_t *plane)
{
int i;
plane_t *pl;
bface_t *f, *nf;
brushhull_t *h;
h = &ex->b->hulls[ex->hullnum];
// see if the plane has allready been added
for (f=h->faces ; f ; f=f->next)
{
pl = f->plane;
if (IPlaneEquiv (plane, pl))
return;
}
nf = malloc(sizeof(*nf));
memset (nf, 0, sizeof(*nf));
nf->planenum = FindIntPlane (plane->inormal, plane->iorigin);
nf->plane = &mapplanes[nf->planenum];
nf->next = h->faces;
nf->contents = CONTENTS_EMPTY;
h->faces = nf;
nf->texinfo = 0; // all clip hulls have same texture
}
/*
============
TestAddPlane
Adds the given plane to the brush description if all of the original brush
vertexes can be put on the front side
=============
*/
void TestAddPlane (expand_t *ex, plane_t *plane)
{
int i, j, c, t;
vec_t d;
vec_t *corner;
plane_t flip;
vec3_t inv;
int counts[3];
plane_t *pl;
bface_t *f, *nf;
brushhull_t *h;
// see if the plane has allready been added
h = &ex->b->hulls[ex->hullnum];
for (f=h->faces ; f ; f=f->next)
{
pl = f->plane;
if (IPlaneEquiv (plane, pl))
return;
}
// check all the corner points
counts[0] = counts[1] = counts[2] = 0;
c = ex->num_hull_points * 8;
corner = ex->hull_corners[0];
for (i=0 ; i<c ; i++, corner += 3)
{
t = 0;
for (j=0 ; j<3 ; j++)
t += (corner[j] - plane->iorigin[j]) * plane->inormal[j];
if (t < 0)
{
if (counts[0])
return;
counts[1]++;
}
else if (t > 0)
{
if (counts[1])
return;
counts[0]++;
}
else
counts[2]++;
}
// the plane is a seperator
if (counts[0])
{
VectorSubtract (vec3_origin, plane->inormal, flip.inormal);
VectorCopy (plane->iorigin, flip.iorigin);
plane = &flip;
}
nf = malloc(sizeof(*nf));
memset (nf, 0, sizeof(*nf));
nf->planenum = FindIntPlane (plane->inormal, plane->iorigin);
nf->plane = &mapplanes[nf->planenum];
nf->next = h->faces;
nf->contents = CONTENTS_EMPTY;
h->faces = nf;
nf->texinfo = 0; // all clip hulls have same texture
}
/*
============
AddHullPoint
Doesn't add if duplicated
=============
*/
int AddHullPoint (expand_t *ex, vec3_t p)
{
int i, j;
vec_t *c;
int x,y,z;
vec3_t r;
for (i=0 ; i<3 ; i++)
r[i] = floor (p[i]+0.5);
for (i=0 ; i<ex->num_hull_points ; i++)
{
for (j=0 ; j<3 ; j++)
if (r[j] != ex->hull_points[i][j])
break;
if (j == 3)
return i; // allready added
}
if (ex->num_hull_points == MAX_HULL_POINTS)
Error ("MAX_HULL_POINTS");
ex->num_hull_points++;
VectorCopy (r, ex->hull_points[ex->num_hull_points]);
c = ex->hull_corners[i*8];
for (x=0 ; x<2 ; x++)
for (y=0 ; y<2 ; y++)
for (z=0; z<2 ; z++)
{
c[0] = r[0] + hull_size[ex->hullnum][x][0];
c[1] = r[1] + hull_size[ex->hullnum][y][1];
c[2] = r[2] + hull_size[ex->hullnum][z][2];
c += 3;
}
return i;
}
/*
============
AddHullEdge
Creates all of the hull planes around the given edge, if not done allready
=============
*/
//#define ANGLEEPSILON 0.00001
#define ANGLEEPSILON ON_EPSILON
void AddHullEdge (expand_t *ex, vec3_t p1, vec3_t p2)
{
int pt1, pt2;
int i;
int a, b, c, d, e;
vec3_t edgevec, planeorg, planevec;
plane_t plane;
vec_t l;
pt1 = AddHullPoint (ex, p1);
pt2 = AddHullPoint (ex, p2);
// now use the rounded values
p1 = ex->hull_points[pt1];
p2 = ex->hull_points[pt2];
for (i=0 ; i<ex->num_hull_edges ; i++)
if ( (ex->hull_edges[i][0] == pt1 && ex->hull_edges[i][1] == pt2)
|| (ex->hull_edges[i][0] == pt2 && ex->hull_edges[i][1] == pt1) )
return; // allread added
if (ex->num_hull_edges == MAX_HULL_EDGES)
Error ("MAX_HULL_EDGES");
ex->hull_edges[i][0] = pt1;
ex->hull_edges[i][1] = pt2;
ex->num_hull_edges++;
VectorSubtract (p1, p2, edgevec);
VectorNormalize (edgevec);
for (a=0 ; a<3 ; a++)
{
b = (a+1)%3;
c = (a+2)%3;
for (d=0 ; d<=1 ; d++)
for (e=0 ; e<=1 ; e++)
{
VectorCopy (p1, plane.iorigin);
plane.iorigin[b] += hull_size[ex->hullnum][d][b];
plane.iorigin[c] += hull_size[ex->hullnum][e][c];
VectorCopy (vec3_origin, planevec);
planevec[a] = 1;
plane.inormal[0] = planevec[1]*edgevec[2] - planevec[2]*edgevec[1];
plane.inormal[1] = planevec[2]*edgevec[0] - planevec[0]*edgevec[2];
plane.inormal[2] = planevec[0]*edgevec[1] - planevec[1]*edgevec[0];
if (!plane.inormal[0] && !plane.inormal[1] && !plane.inormal[2])
continue; // degenerate
TestAddPlane (ex, &plane);
}
}
}
/*
============
ExpandBrush
=============
*/
void ExpandBrush (brush_t *b, int hullnum)
{
int i, x, s;
int corner;
bface_t *brush_faces, *f, *nf;
plane_t *p, plane;
int iorigin[3], inormal[3];
expand_t ex;
brushhull_t *h;
qboolean axial;
brush_faces = b->hulls[0].faces;
h = &b->hulls[hullnum];
ex.b = b;
ex.hullnum = hullnum;
ex.num_hull_points = 0;
ex.num_hull_edges = 0;
// expand all of the planes
axial = true;
for (f=brush_faces ; f ; f=f->next)
{
p = f->plane;
if (p->type > PLANE_Z)
axial = false; // not an xyz axial plane
VectorCopy (p->iorigin, iorigin);
VectorCopy (p->inormal, inormal);
for (x=0 ; x<3 ; x++)
{
if (p->normal[x] > 0)
corner = hull_size[hullnum][1][x];
else if (p->normal[x] < 0)
corner = - hull_size[hullnum][0][x];
else
corner = 0;
iorigin[x] += p->normal[x]*corner;
}
nf = malloc(sizeof(*nf));
memset (nf, 0, sizeof(*nf));
nf->planenum = FindIntPlane (inormal, iorigin);
nf->plane = &mapplanes[nf->planenum];
nf->next = h->faces;
nf->contents = CONTENTS_EMPTY;
h->faces = nf;
nf->texinfo = 0; // all clip hulls have same texture
}
// if this was an axial brush, we are done
if (axial)
return;
#if 1
// add any axis planes not contained in the brush to bevel off corners
for (x=0 ; x<3 ; x++)
for (s=-1 ; s<=1 ; s+=2)
{
// add the plane
VectorCopy (vec3_origin, plane.inormal);
plane.inormal[x] = s;
if (s == -1)
{
VectorAdd (b->hulls[0].mins, hull_size[hullnum][0], plane.iorigin);
}
else
{
VectorAdd (b->hulls[0].maxs, hull_size[hullnum][1], plane.iorigin);
}
AddBrushPlane (&ex, &plane);
}
#endif
#if 0
// create all the hull points
for (f=brush_faces ; f ; f=f->next)
for (i=0 ; i<f->w->numpoints ; i++)
AddHullPoint (&ex, f->w->p[i]);
// add all of the edge bevels
for (f=brush_faces ; f ; f=f->next)
for (i=0 ; i<f->w->numpoints ; i++)
AddHullEdge (&ex, f->w->p[i], f->w->p[(i+1)%f->w->numpoints]);
#endif
}
//============================================================================
/*
===========
MakeHullFaces
===========
*/
void MakeHullFaces (brush_t *b, brushhull_t *h)
{
bface_t *f, *f2;
winding_t *w;
plane_t *p;
int i, j;
vec_t v;
vec_t area;
restart:
h->mins[0] = h->mins[1] = h->mins[2] = 9999;
h->maxs[0] = h->maxs[1] = h->maxs[2] = -9999;
for (f = h->faces ; f ; f=f->next)
{
// w = BaseWindingForIPlane (f->plane);
w = BaseWindingForPlane (f->plane->normal, f->plane->dist);
for (f2 = h->faces ; f2 && w ; f2=f2->next)
{
if (f == f2)
continue;
p = &mapplanes[f2->planenum ^ 1];
w = ChopWinding (w, p->normal, p->dist);
}
area = w ? WindingArea(w) : 0;
if (area < 0.1)
{
qprintf ("Entity %i, Brush %i: plane with area %4.2f\n"
, b->entitynum, b->brushnum, area);
// remove the face and regenerate the hull
if (h->faces == f)
h->faces = f->next;
else
{
for (f2=h->faces ; f2->next != f ; f2=f2->next)
;
f2->next = f->next;
}
goto restart;
}
f->w = w;
f->contents = CONTENTS_EMPTY;
if (w)
{
for (i=0 ; i<w->numpoints ; i++)
{
for (j=0 ; j<3 ; j++)
{
v = w->p[i][j];
// w->p[i][j] = floor (v+0.5); // round to int
if (v<h->mins[j])
h->mins[j] = v;
if (v>h->maxs[j])
h->maxs[j] = v;
}
}
}
}
for (i=0 ; i<3 ; i++)
{
if (h->mins[i] < -BOGUS_RANGE/2
|| h->maxs[i] > BOGUS_RANGE/2)
{
vec3_t eorigin = { 0, 0, 0};
char *pszClass = "Unknown Class";
if ( b->entitynum )
{
entity_t *e = entities + b->entitynum;
pszClass = ValueForKey(e, "classname" );
GetVectorForKey( e, "origin", eorigin );
}
printf( "Entity %i, Brush %i: A '%s' @(%.0f,%.0f,%.0f)\n",
b->entitynum, b->brushnum, pszClass, eorigin[0], eorigin[1], eorigin[2] );
printf( "\toutside world(+/-%d): (%.0f, %.0f, %.0f)-(%.0f,%.0f,%.0f)\n",
BOGUS_RANGE/2, h->mins[0], h->mins[1], h->mins[2], h->maxs[0], h->maxs[1], h->maxs[2] );
break;
}
}
}
/*
===========
MakeBrushPlanes
===========
*/
qboolean MakeBrushPlanes (brush_t *b)
{
int i, j;
int planenum;
side_t *s;
int contents;
bface_t *f;
vec3_t origin;
//
// if the origin key is set (by an origin brush), offset all of the values
//
GetVectorForKey (&entities[b->entitynum], "origin", origin);
//
// convert to mapplanes
//
for (i=0 ; i<b->numsides ; i++)
{
s = &brushsides[b->firstside + i];
for (j=0 ; j<3 ; j++)
{
VectorSubtract (s->planepts[j], origin, s->planepts[j]);
}
planenum = PlaneFromPoints (s->planepts[0], s->planepts[1], s->planepts[2]);
if (planenum == -1)
{
printf ("Entity %i, Brush %i: plane with no normal\n"
, b->entitynum, b->brushnum);
continue;
}
//
// see if the plane has been used already
//
for (f=b->hulls[0].faces ; f ; f=f->next)
{
if (f->planenum == planenum || f->planenum == (planenum^1) )
{
char *pszClass = "Unknown Class";
if ( b->entitynum )
{
entity_t *e = entities + b->entitynum;
pszClass = ValueForKey(e, "classname" );
}
printf( "Entity %i, Brush %i: A '%s' @(%.0f,%.0f,%.0f) has a coplanar plane at (%.0f, %.0f, %.0f), texture %s\n",
b->entitynum, b->brushnum, pszClass, origin[0], origin[1], origin[2], s->planepts[0][0]+origin[0], s->planepts[0][1]+origin[1], s->planepts[0][2]+origin[2], s->td.name );
return false;
}
}
f = malloc(sizeof(*f));
memset (f, 0, sizeof(*f));
f->planenum = planenum;
f->plane = &mapplanes[planenum];
f->next = b->hulls[0].faces;
b->hulls[0].faces = f;
f->texinfo = onlyents ? 0 : TexinfoForBrushTexture (f->plane, &s->td, origin);
}
return true;
}
/*
===========
TextureContents
===========
*/
int TextureContents (char *name)
{
if (!Q_strncasecmp (name, "sky",3))
return CONTENTS_SKY;
if (!Q_strncasecmp(name+1,"!lava",5))
return CONTENTS_LAVA;
if (!Q_strncasecmp(name+1,"!slime",6))
return CONTENTS_SLIME;
if (!Q_strncasecmp (name, "!cur_90",7))
return CONTENTS_CURRENT_90;
if (!Q_strncasecmp (name, "!cur_0",6))
return CONTENTS_CURRENT_0;
if (!Q_strncasecmp (name, "!cur_270",8))
return CONTENTS_CURRENT_270;
if (!Q_strncasecmp (name, "!cur_180",8))
return CONTENTS_CURRENT_180;
if (!Q_strncasecmp (name, "!cur_up",7))
return CONTENTS_CURRENT_UP;
if (!Q_strncasecmp (name, "!cur_dwn",8))
return CONTENTS_CURRENT_DOWN;
if (name[0] == '!')
return CONTENTS_WATER;
if (!Q_strncasecmp (name, "origin",6))
return CONTENTS_ORIGIN;
if (!Q_strncasecmp (name, "clip",4))
return CONTENTS_CLIP;
if( !Q_strncasecmp( name, "translucent", 11 ) )
return CONTENTS_TRANSLUCENT;
if( name[0] == '@' )
return CONTENTS_TRANSLUCENT;
return CONTENTS_SOLID;
}
/*
===========
BrushContents
===========
*/
int BrushContents (brush_t *b)
{
char *name;
int contents;
bface_t *f;
side_t *s;
int i;
s = &brushsides[b->firstside];
contents = TextureContents (s->td.name);
for (i=1 ; i<b->numsides ; i++, s++)
{
if (TextureContents(s->td.name) != contents)
{
printf ("Entity %i, Brush %i: mixed face contents"
, b->entitynum, b->brushnum);
break;
}
}
return contents;
}
/*
===========
CreateBrush
===========
*/
void CreateBrush (int brushnum)
{
brush_t *b;
int contents;
int h;
SetThreadPriority(GetCurrentThread(),THREAD_PRIORITY_ABOVE_NORMAL);
b = &mapbrushes[brushnum];
contents = b->contents;
if (contents == CONTENTS_ORIGIN)
return;
//
// convert brush sides to planes
//
MakeBrushPlanes (b);
MakeHullFaces (b, &b->hulls[0]);
// water brushes are not solid, so are not represented in
// the clipping hull
if (contents == CONTENTS_LAVA
|| contents == CONTENTS_SLIME
|| contents == CONTENTS_WATER
|| contents == CONTENTS_TRANSLUCENT )
return;
if (!noclip)
{
for (h=1 ; h<NUM_HULLS ; h++)
{
ExpandBrush (b, h);
MakeHullFaces (b, &b->hulls[h]);
}
}
// clip brushes don't stay in the drawing hull
if (contents == CONTENTS_CLIP)
{
b->hulls[0].faces = NULL;
b->contents = CONTENTS_SOLID;
}
}