1
0
Fork 0
forked from fte/fteqw
fteqw/engine/client/r_d3.c

1462 lines
39 KiB
C
Raw Normal View History

#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