-void SUB_Null() {}
-float SUB_True() { return 1; }
-float SUB_False() { return 0; }
+void SUB_NullThink(void) { }
void() SUB_CalcMoveDone;
void() SUB_CalcAngleMoveDone;
//print(ftos(time), " -> ", ftos(e.frame), "\n");
}
-vector animfixfps(entity e, vector a)
-{
- // multi-frame anim: keep as-is
- if(a_y == 1)
- {
- float dur;
- dur = frameduration(e.modelindex, a_x);
- if(dur > 0)
- a_z = 1.0 / dur;
- }
- return a;
-}
-
/*
==================
SUB_Remove
*/
void SUB_VanishOrRemove (entity ent)
{
- if (ent.flags & FL_CLIENT)
+ if (IS_CLIENT(ent))
{
// vanish
ent.alpha = -1;
*/
void SUB_SetFade (entity ent, float when, float fadetime)
{
- //if (ent.flags & FL_CLIENT) // && ent.deadflag != DEAD_NO)
- // return;
- //ent.alpha = 1;
ent.fade_rate = 1/fadetime;
ent.think = SUB_SetFade_Think;
ent.nextthink = when;
self.think1 ();
}
-.float bezier_turn;
+.float platmovetype_turn;
void SUB_CalcMove_controller_think (void)
{
entity oldself;
vector delta;
vector delta2;
vector veloc;
+ vector angloc;
vector nextpos;
delta = self.destvec;
delta2 = self.destvec2;
traveltime = self.animstate_endtime - self.animstate_starttime;
phasepos = (nexttick - self.animstate_starttime) / traveltime; // range: [0, 1]
- if(!self.platmovetype)
- self.platmovetype = 2; // default
- switch(self.platmovetype)
- {
- case 1: // linear
- break;
- case 2: // cosine
- phasepos = 3.14159265 + (phasepos * 3.14159265); // range: [pi, 2pi]
- phasepos = cos(phasepos); // cos [pi, 2pi] is in [-1, 1]
- phasepos = phasepos + 1; // correct range to [0, 2]
- phasepos = phasepos / 2; // correct range to [0, 1]
- break;
- case 2: // sine
- phasepos = 3.14159265 + (phasepos * 3.14159265); // range: [pi, 2pi]
- phasepos = sin(phasepos); // sin [pi, 2pi] is in [-1, 1]
- phasepos = phasepos + 1; // correct range to [0, 2]
- phasepos = phasepos / 2; // correct range to [0, 1]
- break;
- }
+ phasepos = cubic_speedfunc(self.platmovetype_start, self.platmovetype_end, phasepos);
nextpos = self.origin + (delta * phasepos) + (delta2 * phasepos * phasepos);
// derivative: delta + 2 * delta2 * phasepos (e.g. for angle positioning)
- if(nexttick < self.animstate_endtime) {
+ if(self.owner.platmovetype_turn)
+ {
+ vector destangle;
+ destangle = delta + 2 * delta2 * phasepos;
+ destangle = vectoangles(destangle);
+ destangle_x = -destangle_x; // flip up / down orientation
+
+ // take the shortest distance for the angles
+ self.owner.angles_x -= 360 * floor((self.owner.angles_x - destangle_x) / 360 + 0.5);
+ self.owner.angles_y -= 360 * floor((self.owner.angles_y - destangle_y) / 360 + 0.5);
+ self.owner.angles_z -= 360 * floor((self.owner.angles_z - destangle_z) / 360 + 0.5);
+ angloc = destangle - self.owner.angles;
+ angloc = angloc * (1 / sys_frametime); // so it arrives for the next frame
+ self.owner.avelocity = angloc;
+ }
+ if(nexttick < self.animstate_endtime)
veloc = nextpos - self.owner.origin;
- veloc = veloc * (1 / sys_frametime); // so it arrives for the next frame
- } else {
+ else
veloc = self.finaldest - self.owner.origin;
- veloc = veloc * (1 / sys_frametime); // so it arrives for the next frame
- }
+ veloc = veloc * (1 / sys_frametime); // so it arrives for the next frame
+
self.owner.velocity = veloc;
- if(self.owner.bezier_turn)
- {
- vector vel;
- vel = delta + 2 * delta2 * phasepos;
- vel_z = -vel_z; // invert z velocity
- vel = vectoangles(vel);
- self.owner.angles = vel;
- }
self.nextthink = nexttick;
} else {
// derivative: delta + 2 * delta2 (e.g. for angle positioning)
controller.classname = "SUB_CalcMove_controller";
controller.owner = self;
controller.platmovetype = self.platmovetype;
+ controller.platmovetype_start = self.platmovetype_start;
+ controller.platmovetype_end = self.platmovetype_end;
SUB_CalcMove_controller_setbezier(controller, self.origin, tcontrol, tdest);
controller.finaldest = (tdest + '0 0 0.125'); // where do we want to end? Offset to overshoot a bit.
controller.animstate_starttime = time;
controller.think1 = self.think;
// the thinking is now done by the controller
- self.think = SUB_Null;
+ self.think = SUB_NullThink; // for PushMove
self.nextthink = self.ltime + traveltime;
// invoke controller
// of controlled animation, so let's just use linear movement.
// Alternatively entities can choose to specify non-controlled movement.
// The only currently implemented alternative movement is linear (value 1)
- if (traveltime < 0.15 || self.platmovetype < 2)
+ if (traveltime < 0.15 || (self.platmovetype_start == 1 && self.platmovetype_end == 1)) // is this correct?
{
self.velocity = delta * (1/traveltime); // QuakeC doesn't allow vector/float division
self.nextthink = self.ltime + traveltime;
// check whether antilagged traces are enabled
if (lag < 0.001)
lag = 0;
- if (clienttype(forent) != CLIENTTYPE_REAL)
+ if not(IS_REAL_CLIENT(forent))
lag = 0; // only antilag for clients
// change shooter to SOLID_BBOX so the shot can hit corpses
tracebox_antilag_force_wz(source, v1, mi, ma, v2, nomonst, forent, lag, TRUE);
}
-float tracebox_inverted (vector v1, vector mi, vector ma, vector v2, float nomonsters, entity forent) // returns the number of traces done, for benchmarking
+float tracebox_inverted (vector v1, vector mi, vector ma, vector v2, float nomonsters, entity forent, float stopatentity) // returns the number of traces done, for benchmarking
{
vector pos, dir, t;
float nudge;
+ entity stopentity;
//nudge = 2 * cvar("collision_impactnudge"); // why not?
nudge = 0.5;
dprint(" trace distance is ", ftos(vlen(pos - trace_endpos)), "\n");
}
+ stopentity = trace_ent;
+
if(trace_startsolid)
{
// we started inside solid.
// t is still inside solid? bad
// force advance, then, and retry
pos = t + dir * nudge;
+
+ // but if we hit an entity, stop RIGHT before it
+ if(stopatentity && stopentity)
+ {
+ trace_ent = stopentity;
+ trace_endpos = t;
+ trace_fraction = ((trace_endpos - v1) * dir) / ((v2 - v1) * dir);
+ return c;
+ }
}
else
{
}
}
-void traceline_inverted (vector v1, vector v2, float nomonsters, entity forent)
+void traceline_inverted (vector v1, vector v2, float nomonsters, entity forent, float stopatentity)
{
-#if 0
- vector pos, dir, t;
- float nudge;
-
- //nudge = 2 * cvar("collision_impactnudge"); // why not?
- nudge = 0.5;
-
- dir = normalize(v2 - v1);
-
- pos = v1 + dir * nudge;
-
- for(;;)
- {
- if((pos - v1) * dir >= (v2 - v1) * dir)
- {
- // went too far
- trace_fraction = 1;
- return;
- }
-
- traceline(pos, v2, nomonsters, forent);
-
- if(trace_startsolid)
- {
- // we started inside solid.
- // then trace from endpos to pos
- t = trace_endpos;
- traceline(t, pos, nomonsters, forent);
- if(trace_startsolid)
- {
- // t is inside solid? bad
- // force advance, then
- pos = pos + dir * nudge;
- }
- else
- {
- // we actually LEFT solid!
- trace_fraction = ((trace_endpos - v1) * dir) / ((v2 - v1) * dir);
- return;
- }
- }
- else
- {
- // pos is outside solid?!? but why?!? never mind, just return it.
- trace_endpos = pos;
- trace_fraction = ((trace_endpos - v1) * dir) / ((v2 - v1) * dir);
- return;
- }
- }
-#else
- tracebox_inverted(v1, '0 0 0', '0 0 0', v2, nomonsters, forent);
+ tracebox_inverted(v1, '0 0 0', '0 0 0', v2, nomonsters, forent, stopatentity);
}
/*
if(self.model != "")
{
precache_model(self.model);
- setmodel(self, self.model); // no precision needed
+ if(self.mins != '0 0 0' || self.maxs != '0 0 0')
+ {
+ vector mi = self.mins;
+ vector ma = self.maxs;
+ setmodel(self, self.model); // no precision needed
+ setsize(self, mi, ma);
+ }
+ else
+ setmodel(self, self.model); // no precision needed
InitializeEntity(self, LODmodel_attach, INITPRIO_FINDTARGET);
}
setorigin(self, self.origin);
if(self.model != "")
{
precache_model(self.model);
- setmodel(self, self.model); // no precision needed
+ if(self.mins != '0 0 0' || self.maxs != '0 0 0')
+ {
+ vector mi = self.mins;
+ vector ma = self.maxs;
+ setmodel(self, self.model); // no precision needed
+ setsize(self, mi, ma);
+ }
+ else
+ setmodel(self, self.model); // no precision needed
}
setorigin(self, self.origin);
ApplyMinMaxScaleAngles(self);