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fteqw/engine/client/r_d3.c
Spoike 03d96bff72 first attempt at webvr support. probably totally crap.
fix hitmodel with skeletal models(can also now support lerps, skeletal objects, etc).
more hlmdl fixes for eukara, including hitboxes.
modelviewer can now display bones.

git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@5033 fc73d0e0-1445-4013-8a0c-d673dee63da5
2016-12-19 13:31:05 +00:00

1461 lines
39 KiB
C

#include "quakedef.h"
#ifdef MAP_PROC
#ifndef SERVERONLY
#include "shader.h"
#endif
#include "com_mesh.h"
//FIXME: shadowmaps should build a cache of the nearby area surfaces and flag those models as RF_NOSHADOW or something
//fixme: merge areas and static ents too somehow.
void Mod_SetParent (mnode_t *node, mnode_t *parent);
static int D3_ClusterForPoint (struct model_s *model, vec3_t point);
#ifndef SERVERONLY
void ModD3_GenAreaVBO(void *ctx, void *data, size_t a, size_t b)
{
model_t *sub = ctx;
BE_GenBrushModelVBO(sub);
}
static void R_BuildDefaultTexnums_Doom3(shader_t *shader)
{
extern qboolean r_loadbumpmapping;
extern cvar_t gl_specular;
extern cvar_t r_fb_bmodels;
char *h;
char imagename[MAX_QPATH];
char mapname[MAX_QPATH];
char *subpath = NULL;
texnums_t *tex;
unsigned int a, aframes;
unsigned int imageflags = 0;
strcpy(imagename, shader->name);
h = strchr(imagename, '#');
if (h)
*h = 0;
if (*imagename == '/' || strchr(imagename, ':'))
{ //this is not security. this is anti-spam for the verbose security in the filesystem code.
Con_Printf("Warning: shader has absolute path: %s\n", shader->name);
*imagename = 0;
}
tex = shader->defaulttextures;
aframes = max(1, shader->numdefaulttextures);
//if any were specified explicitly, replicate that into all.
//this means animmap can be used, with any explicit textures overriding all.
for (a = 1; a < aframes; a++)
{
if (!TEXVALID(tex[a].base))
tex[a].base = tex[0].base;
if (!TEXVALID(tex[a].bump))
tex[a].bump = tex[0].bump;
if (!TEXVALID(tex[a].fullbright))
tex[a].fullbright = tex[0].fullbright;
if (!TEXVALID(tex[a].specular))
tex[a].specular = tex[0].specular;
if (!TEXVALID(tex[a].loweroverlay))
tex[a].loweroverlay = tex[0].loweroverlay;
if (!TEXVALID(tex[a].upperoverlay))
tex[a].upperoverlay = tex[0].upperoverlay;
if (!TEXVALID(tex[a].reflectmask))
tex[a].reflectmask = tex[0].reflectmask;
if (!TEXVALID(tex[a].reflectcube))
tex[a].reflectcube = tex[0].reflectcube;
}
for (a = 0; a < aframes; a++, tex++)
{
COM_StripExtension(tex->mapname, mapname, sizeof(mapname));
if (!TEXVALID(tex->base))
{
/*dlights/realtime lighting needs some stuff*/
if (!TEXVALID(tex->base) && *tex->mapname)// && (shader->flags & SHADER_HASDIFFUSE))
tex->base = R_LoadHiResTexture(tex->mapname, NULL, 0);
if (!TEXVALID(tex->base))
tex->base = R_LoadHiResTexture(va("%s_d", imagename), subpath, (*imagename=='{')?0:IF_NOALPHA);
}
imageflags |= IF_LOWPRIORITY;
COM_StripExtension(imagename, imagename, sizeof(imagename));
if (!TEXVALID(tex->bump))
{
if ((shader->flags & SHADER_HASNORMALMAP) && r_loadbumpmapping)
{
if (!TEXVALID(tex->bump) && *mapname && (shader->flags & SHADER_HASNORMALMAP))
tex->bump = R_LoadHiResTexture(va("%s_local", mapname), NULL, imageflags|IF_TRYBUMP);
if (!TEXVALID(tex->bump))
tex->bump = R_LoadHiResTexture(va("%s_local", imagename), subpath, imageflags|IF_TRYBUMP);
}
}
if (!TEXVALID(tex->loweroverlay))
{
if (shader->flags & SHADER_HASTOPBOTTOM)
{
if (!TEXVALID(tex->loweroverlay) && *mapname)
tex->loweroverlay = R_LoadHiResTexture(va("%s_pants", mapname), NULL, imageflags);
if (!TEXVALID(tex->loweroverlay))
tex->loweroverlay = R_LoadHiResTexture(va("%s_pants", imagename), subpath, imageflags); /*how rude*/
}
}
if (!TEXVALID(tex->upperoverlay))
{
if (shader->flags & SHADER_HASTOPBOTTOM)
{
if (!TEXVALID(tex->upperoverlay) && *mapname)
tex->upperoverlay = R_LoadHiResTexture(va("%s_shirt", mapname), NULL, imageflags);
if (!TEXVALID(tex->upperoverlay))
tex->upperoverlay = R_LoadHiResTexture(va("%s_shirt", imagename), subpath, imageflags);
}
}
if (!TEXVALID(tex->specular))
{
if ((shader->flags & SHADER_HASGLOSS) && gl_specular.value)
{
if (!TEXVALID(tex->specular) && *mapname)
tex->specular = R_LoadHiResTexture(va("%s_s", mapname), NULL, imageflags);
if (!TEXVALID(tex->specular))
tex->specular = R_LoadHiResTexture(va("%s_s", imagename), subpath, imageflags);
}
}
if (!TEXVALID(tex->fullbright))
{
if ((shader->flags & SHADER_HASFULLBRIGHT) && r_fb_bmodels.value && gl_load24bit.value)
{
if (!TEXVALID(tex->fullbright) && *mapname)
tex->fullbright = R_LoadHiResTexture(va("%s_luma:%s_glow", mapname, mapname), NULL, imageflags);
if (!TEXVALID(tex->fullbright))
tex->fullbright = R_LoadHiResTexture(va("%s_luma:%s_glow", imagename, imagename), subpath, imageflags);
}
}
}
}
static qboolean Mod_LoadMap_Proc(model_t *model, char *data)
{
char token[256];
int ver = 0;
data = COM_ParseOut(data, token, sizeof(token));
if (!strcmp(token, "mapProcFile003"))
ver = 3;
if (!strcmp(token, "PROC"))
{
data = COM_ParseOut(data, token, sizeof(token));
ver = atoi(token);
}
if (ver != 3 && ver != 4)
{
Con_Printf("proc format not compatible %s\n", token);
return false;
}
/*FIXME: add sanity checks*/
if (ver == 4)
{
data = COM_ParseOut(data, token, sizeof(token));
}
while(1)
{
data = COM_ParseOut(data, token, sizeof(token));
if (!data)
break;
else if (!strcmp(token, "model"))
{
batch_t *b;
mesh_t *m, **ml;
model_t *sub;
float f;
int numsurfs, surf;
int numverts, v, j;
int numindicies;
char *vdata;
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "{"))
return false;
data = COM_ParseOut(data, token, sizeof(token));
sub = Mod_FindName(va("*%s", token));
data = COM_ParseOut(data, token, sizeof(token));
numsurfs = atoi(token);
if (numsurfs < 0 || numsurfs > 10000)
return false;
if (numsurfs)
{
b = ZG_Malloc(&model->memgroup, sizeof(*b) * numsurfs);
m = ZG_Malloc(&model->memgroup, sizeof(*m) * numsurfs);
ml = ZG_Malloc(&model->memgroup, sizeof(*ml) * numsurfs);
}
else
{
b = NULL;
m = NULL;
ml = NULL;
}
sub->numsurfaces = numsurfs;
//ver4 may have a 'sky' field here
vdata = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "{") && strcmp(token, "}"))
{
//sky = atoi(token);
data = vdata;
}
sub->mins[0] = 99999999;
sub->mins[1] = 99999999;
sub->mins[2] = 99999999;
sub->maxs[0] = -99999999;
sub->maxs[1] = -99999999;
sub->maxs[2] = -99999999;
for (surf = 0; surf < numsurfs; surf++)
{
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "{"))
break;
if (!data)
return false;
b[surf].maxmeshes = 1;
b[surf].mesh = &ml[surf];
ml[surf] = &m[surf];
b[surf].lightmap[0] = -1;
b[surf].lightmap[1] = -1;
b[surf].lightmap[2] = -1;
b[surf].lightmap[3] = -1;
b[surf].lmlightstyle[0] = 0;
b[surf].lmlightstyle[1] = 255;
b[surf].lmlightstyle[2] = 255;
b[surf].lmlightstyle[3] = 255;
data = COM_ParseOut(data, token, sizeof(token));
b[surf].shader = R_RegisterShader_Vertex(token);
R_BuildDefaultTexnums_Doom3(b[surf].shader);
data = COM_ParseOut(data, token, sizeof(token));
numverts = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
numindicies = atoi(token);
b[surf].next = sub->batches[b[surf].shader->sort];
sub->batches[b[surf].shader->sort] = &b[surf];
m[surf].numvertexes = numverts;
m[surf].numindexes = numindicies;
vdata = ZG_Malloc(&sub->memgroup, numverts * (sizeof(vecV_t) + sizeof(vec2_t) + sizeof(vec3_t)*3 + sizeof(vec4_t)) + numindicies * sizeof(index_t));
m[surf].colors4f_array[0] = (vec4_t*)vdata;vdata += sizeof(vec4_t)*numverts;
m[surf].xyz_array = (vecV_t*)vdata;vdata += sizeof(vecV_t)*numverts;
m[surf].st_array = (vec2_t*)vdata;vdata += sizeof(vec2_t)*numverts;
m[surf].normals_array = (vec3_t*)vdata;vdata += sizeof(vec3_t)*numverts;
m[surf].snormals_array = (vec3_t*)vdata;vdata += sizeof(vec3_t)*numverts;
m[surf].tnormals_array = (vec3_t*)vdata;vdata += sizeof(vec3_t)*numverts;
m[surf].indexes = (index_t*)vdata;
for (v = 0; v < numverts; v++)
{
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "("))
return false;
data = COM_ParseOut(data, token, sizeof(token));
m[surf].xyz_array[v][0] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].xyz_array[v][1] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].xyz_array[v][2] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].st_array[v][0] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].st_array[v][1] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].normals_array[v][0] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].normals_array[v][1] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
m[surf].normals_array[v][2] = atof(token);
for (j = 0; j < 3; j++)
{
f = m[surf].xyz_array[v][j];
if (f > sub->maxs[j])
sub->maxs[j] = f;
if (f < sub->mins[j])
sub->mins[j] = f;
}
m[surf].colors4f_array[0][v][0] = 1;
m[surf].colors4f_array[0][v][1] = 1;
m[surf].colors4f_array[0][v][2] = 1;
m[surf].colors4f_array[0][v][3] = 1;
data = COM_ParseOut(data, token, sizeof(token));
/*if its not closed yet, there's an optional colour value*/
if (strcmp(token, ")"))
{
m[surf].colors4f_array[0][v][0] = atof(token)/255;
data = COM_ParseOut(data, token, sizeof(token));
m[surf].colors4f_array[0][v][1] = atof(token)/255;
data = COM_ParseOut(data, token, sizeof(token));
m[surf].colors4f_array[0][v][2] = atof(token)/255;
data = COM_ParseOut(data, token, sizeof(token));
m[surf].colors4f_array[0][v][3] = atof(token)/255;
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, ")"))
return false;
}
}
for (v = 0; v < numindicies; v++)
{
data = COM_ParseOut(data, token, sizeof(token));
m[surf].indexes[v] = atoi(token);
}
//generate the s+t vectors according to the normals that we just parsed.
R_Generate_Mesh_ST_Vectors(&m[surf]);
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "}"))
return false;
}
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "}"))
return false;
// sub->loadstate = MLS_LOADED;
sub->fromgame = fg_doom3;
sub->type = mod_brush;
sub->lightmaps.surfstyles = 1;
COM_AddWork(WG_MAIN, ModD3_GenAreaVBO, sub, NULL, MLS_LOADED, 0);
COM_AddWork(WG_MAIN, Mod_ModelLoaded, sub, NULL, MLS_LOADED, 0);
}
else if (!strcmp(token, "shadowModel"))
{
int numverts, v;
int numindexes, i;
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "{"))
return false;
data = COM_ParseOut(data, token, sizeof(token));
//name
data = COM_ParseOut(data, token, sizeof(token));
numverts = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
//nocaps
data = COM_ParseOut(data, token, sizeof(token));
//nofrontcaps
data = COM_ParseOut(data, token, sizeof(token));
numindexes = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
//planebits
for (v = 0; v < numverts; v++)
{
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "("))
return false;
data = COM_ParseOut(data, token, sizeof(token));
//x
data = COM_ParseOut(data, token, sizeof(token));
//y
data = COM_ParseOut(data, token, sizeof(token));
//z
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, ")"))
return false;
}
for (i = 0; i < numindexes; i++)
{
data = COM_ParseOut(data, token, sizeof(token));
}
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "}"))
return false;
}
else if (!strcmp(token, "nodes"))
{
int numnodes, n;
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "{"))
return false;
data = COM_ParseOut(data, token, sizeof(token));
numnodes = atoi(token);
model->nodes = ZG_Malloc(&model->memgroup, sizeof(*model->nodes)*numnodes);
model->planes = ZG_Malloc(&model->memgroup, sizeof(*model->planes)*numnodes);
for (n = 0; n < numnodes; n++)
{
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "("))
return false;
model->nodes[n].plane = &model->planes[n];
data = COM_ParseOut(data, token, sizeof(token));
model->planes[n].normal[0] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
model->planes[n].normal[1] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
model->planes[n].normal[2] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
model->planes[n].dist = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, ")"))
return false;
data = COM_ParseOut(data, token, sizeof(token));
model->nodes[n].childnum[0] = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
model->nodes[n].childnum[1] = atoi(token);
}
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "}"))
return false;
Mod_SetParent(model->nodes, NULL);
}
else if (!strcmp(token, "interAreaPortals"))
{
//int numareas;
int pno, v;
portal_t *p;
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "{"))
return false;
data = COM_ParseOut(data, token, sizeof(token));
model->numclusters = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
model->numportals = atoi(token);
model->portal = p = ZG_Malloc(&model->memgroup, sizeof(*p) * model->numportals);
for (pno = 0; pno < model->numportals; pno++, p++)
{
data = COM_ParseOut(data, token, sizeof(token));
p->numpoints = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
p->area[0] = atoi(token);
data = COM_ParseOut(data, token, sizeof(token));
p->area[1] = atoi(token);
p->points = ZG_Malloc(&model->memgroup, sizeof(*p->points) * p->numpoints);
ClearBounds(p->min, p->max);
for (v = 0; v < p->numpoints; v++)
{
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "("))
return false;
data = COM_ParseOut(data, token, sizeof(token));
p->points[v][0] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
p->points[v][1] = atof(token);
data = COM_ParseOut(data, token, sizeof(token));
p->points[v][2] = atof(token);
p->points[v][3] = 1;
AddPointToBounds(p->points[v], p->min, p->max);
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, ")"))
return false;
}
}
data = COM_ParseOut(data, token, sizeof(token));
if (strcmp(token, "}"))
return false;
}
else
{
Con_Printf("unexpected token %s\n", token);
return false;
}
}
return true;
}
qboolean R_CullBox (vec3_t mins, vec3_t maxs);
static int walkno;
/*fixme: convert each portal to a 2d box, because its much much simpler than true poly clipping*/
/*fixme: use occlusion tests, with temporal coherance (draw the portal as black or something if we think its invisible)*/
static void D3_WalkPortal(model_t *mod, int start, vec_t bounds[4], unsigned char *vis)
{
int i;
portal_t *p;
int side;
vec_t newbounds[4];
vis[start>>3] |= 1<<(start&7);
for (i = 0; i < mod->numportals; i++)
{
p = mod->portal+i;
if (p->walkno == walkno)
continue;
if (p->area[0] == start)
side = 0;
else if (p->area[1] == start)
side = 1;
else
continue;
if (R_CullBox(p->min, p->max))
{
continue;
}
p->walkno = walkno;
D3_WalkPortal(mod, p->area[!side], newbounds, vis);
}
}
unsigned char *D3_CalcVis(model_t *mod, vec3_t org)
{
int start;
static qbyte visbuf[256];
qbyte *usevis;
vec_t newbounds[4];
int area;
entity_t ent;
start = D3_ClusterForPoint(mod, org);
/*figure out which area we're in*/
if (start < 0)
{
/*outside the world, just make it all visible, and take the fps hit*/
memset(visbuf, 255, 4);
usevis = visbuf;
}
else if (r_novis.value)
usevis = visbuf;
else
{
memset(visbuf, 0, 4);
/*make a bounds the size of the view*/
newbounds[0] = -1;
newbounds[1] = 1;
newbounds[2] = -1;
newbounds[3] = 1;
walkno++;
D3_WalkPortal(mod, start, newbounds, visbuf);
// Con_Printf("%x %x %x %x\n", vis[0], vis[1], vis[2], vis[3]);
usevis = visbuf;
}
//now generate the various entities for that region.
memset(&ent, 0, sizeof(ent));
for (area = 0; area < 256*8; area++)
{
if (usevis[area>>3] & (1u<<(area&7)))
{
ent.model = Mod_FindName(va("*_area%i", area));
ent.scale = 1;
AngleVectors(ent.angles, ent.axis[0], ent.axis[1], ent.axis[2]);
VectorInverse(ent.axis[1]);
ent.shaderRGBAf[0] = 1;
ent.shaderRGBAf[1] = 1;
ent.shaderRGBAf[2] = 1;
ent.shaderRGBAf[3] = 1;
V_AddEntity(&ent);
}
}
return usevis;
}
#endif
//edict system as opposed to q2 game dll system.
static void D3_FindTouchedLeafs (struct model_s *model, struct pvscache_s *ent, vec3_t cullmins, vec3_t cullmaxs)
{
}
static qbyte *D3_ClusterPVS (struct model_s *model, int num, qbyte *buffer, unsigned int buffersize)
{
memset(buffer, 0xff, buffersize);
return buffer;
}
static int D3_ClusterForPoint (struct model_s *model, vec3_t point)
{
float p;
int c;
mnode_t *node;
node = model->nodes;
while(1)
{
p = DotProduct(point, node->plane->normal) + node->plane->dist;
c = node->childnum[p<0];
if (c <= 0)
return -1-c;
node = model->nodes + c;
}
return 0;
}
static unsigned int D3_FatPVS (struct model_s *model, vec3_t org, qbyte *pvsbuffer, unsigned int buffersize, qboolean merge)
{
return 0;
}
static void D3_StainNode (struct mnode_s *node, float *parms)
{
}
static void D3_LightPointValues (struct model_s *model, vec3_t point, vec3_t res_diffuse, vec3_t res_ambient, vec3_t res_dir)
{
/*basically require rtlighting for any light*/
VectorClear(res_diffuse);
VectorClear(res_ambient);
VectorClear(res_dir);
res_dir[2] = 1;
}
static qboolean D3_EdictInFatPVS (struct model_s *model, struct pvscache_s *edict, qbyte *pvsbuffer)
{
int i;
for (i = 0; i < edict->num_leafs; i++)
if (pvsbuffer[edict->leafnums[i]>>3] & (1u<<(edict->leafnums[i]&7)))
return true;
return false;
}
typedef struct cm_surface_s
{
vec3_t mins, maxs;
vec4_t plane;
int numedges;
vec4_t *edge;
// shader_t *shader;
struct cm_surface_s *next;
} cm_surface_t;
typedef struct cm_brush_s
{
vec3_t mins, maxs;
int numplanes;
vec4_t *plane;
unsigned int contents;
struct cm_brush_s *next;
} cm_brush_t;
typedef struct cm_node_s
{
int axis; /*0=x,1=y,2=z*/
float dist;
vec3_t mins, maxs;
struct cm_node_s *parent;
struct cm_node_s *child[2];
cm_brush_t *brushlist;
cm_surface_t *surfacelist;
} cm_node_t;
static struct
{
float truefraction;
qboolean ispoint;
vec3_t start;
vec3_t end;
vec3_t absmins, absmaxs;
vec3_t szmins, szmaxs;
vec3_t extents;
cm_surface_t *surf;
} traceinfo;
#define DIST_EPSILON (0.03125)
static void D3_TraceToLeaf (cm_node_t *leaf)
{
float diststart;
float distend;
float frac;
vec3_t impactpoint;
qboolean back;
int i, j;
float pdist, expand;
vec3_t ofs;
cm_surface_t *surf;
for (surf = leaf->surfacelist; surf; surf = surf->next)
{
/*lots of maths in this function, we should check the surf's bbox*/
if (surf->mins[0] > traceinfo.absmaxs[0] || traceinfo.absmins[0] > surf->maxs[0] ||
surf->mins[1] > traceinfo.absmaxs[1] || traceinfo.absmins[1] > surf->maxs[1] ||
surf->mins[2] > traceinfo.absmaxs[2] || traceinfo.absmins[2] > surf->maxs[2])
continue;
if (!traceinfo.ispoint)
{ // general box case
// push the plane out apropriately for mins/maxs
// FIXME: use signbits into 8 way lookup for each mins/maxs
for (i=0 ; i<3 ; i++)
{
if (surf->plane[i] < 0)
ofs[i] = traceinfo.szmaxs[i];
else
ofs[i] = traceinfo.szmins[i];
}
expand = DotProduct (ofs, surf->plane);
// pdist = surf->plane[3] - expand;
}
else
{ // special point case
// pdist = surf->plane[3];
expand = 0;
}
diststart = DotProduct(traceinfo.start, surf->plane);
/*started behind?*/
back = diststart < surf->plane[3];
if (diststart <= surf->plane[3]-expand)
{
/*the trace started behind our expanded front plane*/
/*don't stop just because the point is closer than the extended plane*/
/*epsilon here please*/
if (diststart <= surf->plane[3])
continue;
distend = DotProduct(traceinfo.end, surf->plane);
if (distend < diststart)
frac = 0; /*don't let us go further into the wall*/
else
continue;
}
else
{
distend = DotProduct(traceinfo.end, surf->plane);
/*ended on the other side*/
if (back)
{
if (distend+expand > -surf->plane[3])
continue;
}
else
{
if (distend+expand > surf->plane[3])
continue;
}
if (diststart == distend)
frac = 0;
else
frac = (diststart - (surf->plane[3]-expand)) / (diststart-distend);
}
/*give up if we already found a closer plane*/
if (frac >= traceinfo.truefraction)
continue;
/*okay, this is where it hits this plane*/
impactpoint[0] = traceinfo.start[0] + frac*(traceinfo.end[0] - traceinfo.start[0]);
impactpoint[1] = traceinfo.start[1] + frac*(traceinfo.end[1] - traceinfo.start[1]);
impactpoint[2] = traceinfo.start[2] + frac*(traceinfo.end[2] - traceinfo.start[2]);
/*if the impact was not on the surface*/
for (i = 0; i < surf->numedges; i++)
{
if (!traceinfo.ispoint)
{ // general box case
// push the plane out apropriately for mins/maxs
// FIXME: use signbits into 8 way lookup for each mins/maxs
for (j=0 ; j<3 ; j++)
{
if (surf->edge[i][j] < 0)
ofs[j] = traceinfo.szmaxs[j];
else
ofs[j] = traceinfo.szmins[j];
}
pdist = DotProduct (ofs, surf->edge[i]);
pdist = surf->edge[i][3] - pdist;
}
else
{ // special point case
pdist = surf->edge[i][3];
}
if (DotProduct(impactpoint, surf->edge[i]) > pdist)
{
break;
}
}
/*if we were inside all edges, we hit the surface*/
if (i == surf->numedges)
{
traceinfo.truefraction = frac;
traceinfo.surf = surf;
/*we can't early out. there are multiple surfs in each leaf, and they could overlap. earlying out will result in errors if we hit a further one before the nearer*/
}
}
}
/*returns the most distant node which contains the entire box*/
static cm_node_t *D3_ChildNodeForBox(cm_node_t *node, vec3_t mins, vec3_t maxs)
{
float t1, t2;
for(;;)
{
t1 = mins[node->axis] - node->dist;
t2 = maxs[node->axis] - node->dist;
//if its completely to one side, walk down that side
if (t1 > maxs[node->axis] && t2 > maxs[node->axis])
{
//if this is a leaf, we can't insert in a child anyway.
if (!node->child[0])
break;
node = node->child[0];
continue;
}
if (t1 < mins[node->axis] && t2 < mins[node->axis])
{
//if this is a leaf, we can't insert in a child anyway.
if (!node->child[1])
break;
node = node->child[1];
continue;
}
//the box crosses this node
break;
}
return node;
}
static void D3_InsertClipSurface(cm_node_t *node, cm_surface_t *surf)
{
node = D3_ChildNodeForBox(node, surf->mins, surf->maxs);
surf->next = node->surfacelist;
node->surfacelist = surf;
}
static void D3_InsertClipBrush(cm_node_t *node, cm_brush_t *brush)
{
node = D3_ChildNodeForBox(node, brush->mins, brush->maxs);
brush->next = node->brushlist;
node->brushlist = brush;
}
static void D3_RecursiveSurfCheck (cm_node_t *node, float p1f, float p2f, vec3_t p1, vec3_t p2)
{
float t1, t2, offset;
float frac, frac2;
float idist;
int i;
vec3_t mid;
int side;
float midf;
if (traceinfo.truefraction <= p1f)
return; // already hit something nearer
/*err, no child here*/
if (!node)
return;
D3_TraceToLeaf (node);
//
// find the point distances to the seperating plane
// and the offset for the size of the box
//
t1 = p1[node->axis] - node->dist;
t2 = p2[node->axis] - node->dist;
offset = traceinfo.extents[node->axis];
#if 0
D3_RecursiveHullCheck (node->childnum[0], p1f, p2f, p1, p2);
D3_RecursiveHullCheck (node->childnum[1], p1f, p2f, p1, p2);
return;
#endif
// see which sides we need to consider
if (t1 >= offset && t2 >= offset)
{
D3_RecursiveSurfCheck (node->child[0], p1f, p2f, p1, p2);
return;
}
if (t1 < -offset && t2 < -offset)
{
D3_RecursiveSurfCheck ( node->child[1], p1f, p2f, p1, p2);
return;
}
// put the crosspoint DIST_EPSILON pixels on the near side
if (t1 < t2)
{
idist = 1.0/(t1-t2);
side = 1;
frac2 = (t1 + offset + DIST_EPSILON)*idist;
frac = (t1 - offset + DIST_EPSILON)*idist;
}
else if (t1 > t2)
{
idist = 1.0/(t1-t2);
side = 0;
frac2 = (t1 - offset - DIST_EPSILON)*idist;
frac = (t1 + offset + DIST_EPSILON)*idist;
}
else
{
side = 0;
frac = 1;
frac2 = 0;
}
// move up to the node
if (frac < 0)
frac = 0;
if (frac > 1)
frac = 1;
midf = p1f + (p2f - p1f)*frac;
for (i=0 ; i<3 ; i++)
mid[i] = p1[i] + frac*(p2[i] - p1[i]);
D3_RecursiveSurfCheck (node->child[side], p1f, midf, p1, mid);
// go past the node
if (frac2 < 0)
frac2 = 0;
if (frac2 > 1)
frac2 = 1;
midf = p1f + (p2f - p1f)*frac2;
for (i=0 ; i<3 ; i++)
mid[i] = p1[i] + frac2*(p2[i] - p1[i]);
D3_RecursiveSurfCheck (node->child[side^1], midf, p2f, mid, p2);
}
static qboolean D3_Trace (struct model_s *model, int hulloverride, framestate_t *framestate, vec3_t axis[3], vec3_t p1, vec3_t p2, vec3_t mins, vec3_t maxs, qboolean capsule, unsigned int hitcontentsmask, struct trace_s *trace)
{
int i;
float e1,e2;
traceinfo.truefraction = 1;
VectorCopy(p1, traceinfo.start);
VectorCopy(p2, traceinfo.end);
for (i = 0; i < 3; i++)
{
e1 = fabs(mins[i]);
e2 = fabs(maxs[i]);
traceinfo.extents[i] = ((e1>e2)?e1:e2);
traceinfo.szmins[i] = mins[i];
traceinfo.szmaxs[i] = maxs[i];
traceinfo.absmins[i] = ((p1[i]<p2[i])?p1[i]:p2[i]) + mins[i];
traceinfo.absmaxs[i] = ((p1[i]>p2[i])?p1[i]:p2[i]) + maxs[i];
}
traceinfo.ispoint = !traceinfo.extents[0] && !traceinfo.extents[1] && !traceinfo.extents[2];
traceinfo.surf = NULL;
D3_RecursiveSurfCheck(model->cnodes, 0, 1, p1, p2);
memset(trace, 0, sizeof(*trace));
if (!traceinfo.surf)
{
trace->fraction = 1;
VectorCopy(p2, trace->endpos);
}
else
{
float frac;
/*we now know which surface it hit. recalc the impact point, but with an epsilon this time, so we can never get too close to the surface*/
VectorCopy(traceinfo.surf->plane, trace->plane.normal);
if (!traceinfo.ispoint)
{ // general box case
vec3_t ofs;
// push the plane out apropriately for mins/maxs
// FIXME: use signbits into 8 way lookup for each mins/maxs
for (i=0 ; i<3 ; i++)
{
if (traceinfo.surf->plane[i] < 0)
ofs[i] = traceinfo.szmaxs[i];
else
ofs[i] = traceinfo.szmins[i];
}
e1 = DotProduct (ofs, traceinfo.surf->plane);
trace->plane.dist = traceinfo.surf->plane[3] - e1;
}
else
{ // special point case
trace->plane.dist = traceinfo.surf->plane[3];
}
frac = traceinfo.truefraction;
/*
diststart = DotProduct(traceinfo.start, trace->plane.normal);
distend = DotProduct(traceinfo.end, trace->plane.normal);
if (diststart == distend)
frac = 0;
else
{
frac = (diststart - trace->plane.dist) / (diststart-distend);
if (frac < 0)
frac = 0;
else if (frac > 1)
frac = 1;
}*/
/*okay, this is where it hits this plane*/
trace->endpos[0] = traceinfo.start[0] + frac*(traceinfo.end[0] - traceinfo.start[0]);
trace->endpos[1] = traceinfo.start[1] + frac*(traceinfo.end[1] - traceinfo.start[1]);
trace->endpos[2] = traceinfo.start[2] + frac*(traceinfo.end[2] - traceinfo.start[2]);
trace->fraction = frac;
}
trace->ent = NULL;
return false;
}
static unsigned int D3_PointContents (struct model_s *model, vec3_t axis[3], vec3_t p)
{
cm_node_t *node = model->cnodes;
cm_brush_t *brush;
float t1;
unsigned int contents = 0;
int i;
if (axis)
{
vec3_t tmp;
VectorCopy(p, tmp);
p[0] = DotProduct(tmp, axis[0]);
p[1] = DotProduct(tmp, axis[1]);
p[2] = DotProduct(tmp, axis[2]);
}
while(node)
{
for (brush = node->brushlist; brush; brush = brush->next)
{
if (brush->mins[0] > p[0] || p[0] > brush->maxs[0] ||
brush->mins[1] > p[1] || p[1] > brush->maxs[1] ||
brush->mins[2] > p[2] || p[2] > brush->maxs[2])
continue;
for (i = 0; i < brush->numplanes; i++)
{
if (DotProduct(p, brush->plane[i]) > brush->plane[i][3])
break;
}
if (i == brush->numplanes)
contents |= brush->contents;
}
t1 = p[node->axis] - node->dist;
// see which side we need to go down
if (t1 >= 0)
{
node = node->child[0];
}
else
{
node = node->child[1];
}
}
return contents;
}
#define ensurenewtoken(t) buf = COM_ParseOut(buf, token, sizeof(token)); if (strcmp(token, t)) break;
static int D3_ParseContents(char *str)
{
char *e, *n;
unsigned int contents = 0;
while(str)
{
e = strchr(str, ',');
if (e)
{
*e = 0;
n = e+1;
}
else
n = NULL;
if (!strcmp(str, "solid") || !strcmp(str, "opaque"))
contents |= FTECONTENTS_SOLID;
else if (!strcmp(str, "playerclip"))
contents |= FTECONTENTS_PLAYERCLIP;
else if (!strcmp(str, "monsterclip"))
contents |= FTECONTENTS_PLAYERCLIP;
else
Con_Printf("Unknown contents type \"%s\"\n", str);
str = n;
}
return contents;
}
typedef struct
{
int v[2];
int fl[2];
} d3edge_t;
qboolean QDECL D3_LoadMap_CollisionMap(model_t *mod, void *buf, size_t bufsize)
{
int pedges[64];
cm_surface_t *surf;
cm_brush_t *brush;
vec3_t *verts;
d3edge_t *edges;
int i, j;
int filever = 0;
int numverts, numedges, numpedges;
model_t *cmod;
char token[256];
buf = COM_ParseOut(buf, token, sizeof(token));
if (strcmp(token, "CM"))
return false;
buf = COM_ParseOut(buf, token, sizeof(token));
filever = atof(token);
if (filever != 1 && filever != 3)
return false;
buf = COM_ParseOut(buf, token, sizeof(token));
/*some number, discard*/
while(buf)
{
buf = COM_ParseOut(buf, token, sizeof(token));
if (!strcmp(token, "collisionModel"))
{
buf = COM_ParseOut(buf, token, sizeof(token));
if (!strcmp(token, "worldMap"))
cmod = mod;
else
cmod = Mod_FindName(token);
if (filever == 3)
{
buf = COM_ParseOut(buf, token, sizeof(token));
/*don't know*/
}
ClearBounds(cmod->mins, cmod->maxs);
ensurenewtoken("{");
ensurenewtoken("vertices");
ensurenewtoken("{");
buf = COM_ParseOut(buf, token, sizeof(token));
numverts = atoi(token);
verts = malloc(numverts * sizeof(*verts));
for (i = 0; i < numverts; i++)
{
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
verts[i][0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
verts[i][1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
verts[i][2] = atof(token);
ensurenewtoken(")");
}
ensurenewtoken("}");
ensurenewtoken("edges");
ensurenewtoken("{");
buf = COM_ParseOut(buf, token, sizeof(token));
numedges = atoi(token);
edges = malloc(numedges * sizeof(*edges));
for (i = 0; i < numedges; i++)
{
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
edges[i].v[0] = atoi(token);
buf = COM_ParseOut(buf, token, sizeof(token));
edges[i].v[1] = atoi(token);
ensurenewtoken(")");
buf = COM_ParseOut(buf, token, sizeof(token));
edges[i].fl[0] = atoi(token);
buf = COM_ParseOut(buf, token, sizeof(token));
edges[i].fl[1] = atoi(token);
}
ensurenewtoken("}");
ensurenewtoken("nodes");
ensurenewtoken("{");
cmod->cnodes = ZG_Malloc(&mod->memgroup, sizeof(cm_node_t));
for (;;)
{
buf = COM_ParseOut(buf, token, sizeof(token));
if (strcmp(token, "("))
break;
buf = COM_ParseOut(buf, token, sizeof(token));
buf = COM_ParseOut(buf, token, sizeof(token));
//axis, dist
ensurenewtoken(")");
}
if (strcmp(token, "}"))
break;
ensurenewtoken("polygons");
if (filever == 1)
{
buf = COM_ParseOut(buf, token, sizeof(token));
/*'polygonMemory', which is unusable for us*/
}
else
{
buf = COM_ParseOut(buf, token, sizeof(token));
/*numPolygons*/
buf = COM_ParseOut(buf, token, sizeof(token));
/*numPolygonEdges*/
}
ensurenewtoken("{");
for (;;)
{
buf = COM_ParseOut(buf, token, sizeof(token));
if (!strcmp(token, "}"))
break;
numpedges = atoi(token);
surf = ZG_Malloc(&mod->memgroup, sizeof(*surf) + sizeof(vec4_t)*numpedges);
surf->numedges = numpedges;
surf->edge = (vec4_t*)(surf+1);
ensurenewtoken("(");
for (j = 0; j < numpedges; j++)
{
buf = COM_ParseOut(buf, token, sizeof(token));
pedges[j] = atoi(token);
}
ensurenewtoken(")");
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
surf->plane[0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
surf->plane[1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
surf->plane[2] = atof(token);
ensurenewtoken(")");
buf = COM_ParseOut(buf, token, sizeof(token));
surf->plane[3] = atof(token);
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
surf->mins[0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
surf->mins[1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
surf->mins[2] = atof(token);
ensurenewtoken(")");
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
surf->maxs[0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
surf->maxs[1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
surf->maxs[2] = atof(token);
ensurenewtoken(")");
buf = COM_ParseOut(buf, token, sizeof(token));
#ifndef SERVERONLY
// surf->shader = R_RegisterShader_Vertex(token);
// R_BuildDefaultTexnums_Doom3(NULL, surf->shader);
#endif
if (filever == 3)
{
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
buf = COM_ParseOut(buf, token, sizeof(token));
ensurenewtoken(")");
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
buf = COM_ParseOut(buf, token, sizeof(token));
ensurenewtoken(")");
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
buf = COM_ParseOut(buf, token, sizeof(token));
ensurenewtoken(")");
buf = COM_ParseOut(buf, token, sizeof(token));
}
for (j = 0; j < numpedges; j++)
{
float *v1, *v2;
vec3_t dir;
if (pedges[j] < 0)
{
v2 = verts[edges[-pedges[j]].v[0]];
v1 = verts[edges[-pedges[j]].v[1]];
}
else
{
v1 = verts[edges[pedges[j]].v[0]];
v2 = verts[edges[pedges[j]].v[1]];
}
VectorSubtract(v1, v2, dir);
VectorNormalize(dir);
CrossProduct(surf->plane, dir, surf->edge[j]);
surf->edge[j][3] = DotProduct(v1, surf->edge[j]);
surf->edge[j][3] += DIST_EPSILON;
}
D3_InsertClipSurface(cmod->cnodes, surf);
AddPointToBounds(surf->mins, cmod->mins, cmod->maxs);
AddPointToBounds(surf->maxs, cmod->mins, cmod->maxs);
}
free(verts);
free(edges);
ensurenewtoken("brushes");
if (filever == 1)
{
buf = COM_ParseOut(buf, token, sizeof(token));
/*'brushMemory', which is unusable for us*/
}
else
{
buf = COM_ParseOut(buf, token, sizeof(token));
/*numBrushes */
buf = COM_ParseOut(buf, token, sizeof(token));
/*numBrushPlanes*/
}
ensurenewtoken("{");
for (;;)
{
buf = COM_ParseOut(buf, token, sizeof(token));
if (!strcmp(token, "}"))
break;
j = atoi(token);
brush = ZG_Malloc(&mod->memgroup, j*sizeof(vec4_t) + sizeof(*brush));
brush->numplanes = j;
brush->plane = (vec4_t*)(brush+1);
ensurenewtoken("{");
for (i = 0; i < brush->numplanes; i++)
{
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
brush->plane[i][0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
brush->plane[i][1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
brush->plane[i][2] = atof(token);
ensurenewtoken(")");
buf = COM_ParseOut(buf, token, sizeof(token));
brush->plane[i][3] = atof(token);
}
ensurenewtoken("}");
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
brush->mins[0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
brush->mins[1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
brush->mins[2] = atof(token);
ensurenewtoken(")");
ensurenewtoken("(");
buf = COM_ParseOut(buf, token, sizeof(token));
brush->maxs[0] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
brush->maxs[1] = atof(token);
buf = COM_ParseOut(buf, token, sizeof(token));
brush->maxs[2] = atof(token);
ensurenewtoken(")");
buf = COM_ParseOut(buf, token, sizeof(token));
brush->contents = D3_ParseContents(token);
if (filever == 3)
buf = COM_ParseOut(buf, token, sizeof(token));
D3_InsertClipBrush(cmod->cnodes, brush);
AddPointToBounds(brush->mins, cmod->mins, cmod->maxs);
AddPointToBounds(brush->maxs, cmod->mins, cmod->maxs);
}
}
else
break;
}
/*load up the .map so we can get some entities (anyone going to bother making a qc mod compatible with this?)*/
COM_StripExtension(mod->name, token, sizeof(token));
Mod_SetEntitiesString(mod, FS_LoadMallocFile(va("%s.map", token), NULL), true);
mod->funcs.FindTouchedLeafs = D3_FindTouchedLeafs;
mod->funcs.NativeTrace = D3_Trace;
mod->funcs.PointContents = D3_PointContents;
mod->funcs.FatPVS = D3_FatPVS;
mod->funcs.ClusterForPoint = D3_ClusterForPoint;
mod->funcs.StainNode = D3_StainNode;
mod->funcs.LightPointValues = D3_LightPointValues;
mod->funcs.EdictInFatPVS = D3_EdictInFatPVS;
mod->funcs.ClusterPVS = D3_ClusterPVS;
mod->fromgame = fg_doom3;
/*that's the physics sorted*/
#ifndef SERVERONLY
if (!isDedicated)
{
COM_StripExtension(mod->name, token, sizeof(token));
buf = FS_LoadMallocFile(va("%s.proc", token), NULL);
Mod_LoadMap_Proc(mod, buf);
BZ_Free(buf);
}
#endif
return true;
}
#endif