kingpin-sdk/gamesrc/M_BBOX.C

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2000-03-27 00:00:00 +00:00
#include "g_local.h"
//
// M_BBOX.C
//
#define MAX_MDX_BBOX_ENTITIES 32 // theoretically, this should be MAX_MODEL_PARTS * MAX_MODELPART_OBJECTS
// but that would be too many, so we have to compromise
edict_t *mdx_bbox[MAX_MDX_BBOX_ENTITIES];
void MDX_Bbox_Init (void)
{
int i;
for (i = 0; i < (MAX_MDX_BBOX_ENTITIES); i++)
{
mdx_bbox[i] = G_Spawn();
mdx_bbox[i]->classname = "mdx_bbox";
mdx_bbox[i]->s.modelindex = 0;
mdx_bbox[i]->takedamage = DAMAGE_NO; // don't take damage from explosions, we'll do all damage testing manually
// mdx_bbox[i]->svflags |= SVF_MONSTER;
mdx_bbox[i]->solid |= SOLID_BBOX;
mdx_bbox[i]->flags |= FL_MDXBBOX;
}
}
int bbox_cnt;
trace_t MDX_HitCheck (edict_t *targ, edict_t *inflictor, edict_t *attacker, vec3_t dir, vec3_t point, vec3_t normal, int damage, int knockback, int dflags, int mod, vec3_t end)
{
trace_t tr;
vec3_t forward, right, up;
int sub_object;
int i;
vec3_t rmins, rmaxs; // rotated mins/maxs positions
vec3_t pmins, pmaxs; // perpendicular with world axis
vec3_t org;
bbox_cnt = 0;
AngleVectors (mdx_bbox[bbox_cnt]->s.angles, forward, right, up);
VectorCopy (targ->s.origin, org);
if (targ->cast_info.scale != 1.0)
{
VectorScale( forward, targ->cast_info.scale, forward );
VectorScale( right, targ->cast_info.scale, right );
VectorScale( up, targ->cast_info.scale, up );
org[2] -= 24 * (1.0 - targ->cast_info.scale);
}
for (i=0; i<MAX_MODEL_PARTS; i++)
{
sub_object = 0;
// Ridah, can't shoot the gun, so ignore it, or it'll prevent us from shooting the arm holding it
if (i == PART_GUN)
continue;
while (targ->s.model_parts[i].modelindex)
{
if (!targ->s.model_parts[i].object_bounds[sub_object])
break;
// Ridah, only check visible sub-objects
if (!(targ->s.model_parts[i].invisible_objects & (1<<sub_object)))
{
VectorCopy (org, mdx_bbox[bbox_cnt]->s.origin);
VectorCopy (targ->s.angles, mdx_bbox[bbox_cnt]->s.angles);
VectorCopy (g_objbnds[-1+targ->s.model_parts[i].object_bounds[sub_object]][targ->s.frame].mins, mdx_bbox[bbox_cnt]->mins);
VectorCopy (g_objbnds[-1+targ->s.model_parts[i].object_bounds[sub_object]][targ->s.frame].maxs, mdx_bbox[bbox_cnt]->maxs);
if (targ->cast_info.scale != 1.0)
{
VectorScale( mdx_bbox[bbox_cnt]->mins, targ->cast_info.scale, mdx_bbox[bbox_cnt]->mins );
VectorScale( mdx_bbox[bbox_cnt]->maxs, targ->cast_info.scale, mdx_bbox[bbox_cnt]->maxs );
}
VectorMA (mdx_bbox[bbox_cnt]->s.origin, ((mdx_bbox[bbox_cnt]->mins[0] + mdx_bbox[bbox_cnt]->maxs[0]) * 0.5), forward, mdx_bbox[bbox_cnt]->s.origin);
VectorMA (mdx_bbox[bbox_cnt]->s.origin, -((mdx_bbox[bbox_cnt]->mins[1] + mdx_bbox[bbox_cnt]->maxs[1]) * 0.5), right, mdx_bbox[bbox_cnt]->s.origin);
VectorMA (mdx_bbox[bbox_cnt]->s.origin, (mdx_bbox[bbox_cnt]->mins[2] + mdx_bbox[bbox_cnt]->maxs[2]) * 0.5, up, mdx_bbox[bbox_cnt]->s.origin);
// find rotated positions of mins/maxs, and then build the new min/max
VectorScale ( forward, mdx_bbox[bbox_cnt]->mins[0], rmins);
VectorMA (rmins, -mdx_bbox[bbox_cnt]->mins[1], right, rmins);
VectorMA (rmins, mdx_bbox[bbox_cnt]->mins[2], up, rmins);
VectorScale ( forward, mdx_bbox[bbox_cnt]->maxs[0], rmaxs);
VectorMA (rmaxs, -mdx_bbox[bbox_cnt]->maxs[1], right, rmaxs);
VectorMA (rmaxs, mdx_bbox[bbox_cnt]->maxs[2], up, rmaxs);
pmins[0] = (rmins[0] < rmaxs[0] ? rmins[0] : rmaxs[0]);
pmins[1] = (rmins[1] < rmaxs[1] ? rmins[1] : rmaxs[1]);
pmins[2] = (rmins[2] < rmaxs[2] ? rmins[2] : rmaxs[2]);
pmaxs[0] = (rmins[0] > rmaxs[0] ? rmins[0] : rmaxs[0]);
pmaxs[1] = (rmins[1] > rmaxs[1] ? rmins[1] : rmaxs[1]);
pmaxs[2] = (rmins[2] > rmaxs[2] ? rmins[2] : rmaxs[2]);
// now align the mins/maxs with the origin
mdx_bbox[bbox_cnt]->mins[0] = pmins[0] - (0.5*(pmaxs[0] + pmins[0]));
mdx_bbox[bbox_cnt]->mins[1] = pmins[1] - (0.5*(pmaxs[1] + pmins[1]));
mdx_bbox[bbox_cnt]->mins[2] = pmins[2] - (0.5*(pmaxs[2] + pmins[2]));
mdx_bbox[bbox_cnt]->maxs[0] = pmaxs[0] - (0.5*(pmaxs[0] + pmins[0]));
mdx_bbox[bbox_cnt]->maxs[1] = pmaxs[1] - (0.5*(pmaxs[1] + pmins[1]));
mdx_bbox[bbox_cnt]->maxs[2] = pmaxs[2] - (0.5*(pmaxs[2] + pmins[2]));
mdx_bbox[bbox_cnt]->count = i; // record model part
mdx_bbox[bbox_cnt]->dmg = sub_object; // record sub_object
if (damage > 0)
{
mdx_bbox[bbox_cnt]->solid = SOLID_BBOX;
gi.linkentity (mdx_bbox[bbox_cnt]);
}
bbox_cnt++;
}
sub_object++;
if (bbox_cnt > (MAX_MDX_BBOX_ENTITIES))
{
gi.error ("MDX_HitCheck: too many bbox parts: %d\n", bbox_cnt);
}
if (sub_object == MAX_MODELPART_OBJECTS)
break;
}
}
if (damage > 0)
{
tr = gi.trace (point, NULL, NULL, end, targ, MASK_SHOT );
MDX_Cleanup();
}
else
{
memset( &tr, 0, sizeof(trace_t));
}
/*
// just to see where the hit occured
{
edict_t *e;
e = G_Spawn();
e->s.modelindex = 98;
gi.linkentity(e);
VectorCopy (tr.endpos, e->s.origin);
e->think = G_FreeEdict;
e->nextthink = level.time + 1.0;
// Ridah, debugging, change the skin on this sub-object
if (tr.fraction < 1 && tr.ent->flags & FL_MDXBBOX)
if (++targ->s.model_parts[tr.ent->count].skinnum[tr.ent->dmg] > 4)
targ->s.model_parts[tr.ent->count].skinnum[tr.ent->dmg] = 0;
}
*/
return tr;
}
void MDX_Cleanup (void)
{
int i;
for (i = 0; i < (MAX_MDX_BBOX_ENTITIES); i++)
{
if (mdx_bbox[i]->solid)
{
gi.unlinkentity (mdx_bbox[i]);
mdx_bbox[i]->solid = 0;
}
}
}