public Vector3 GetVelocity(Vector3 pos)
{
if (source)
{
MegaFlowFrame frame = source.frames[framenum];
if (frame && frame.GetGridVel != null)
{
return(frame.GetGridVelWorld(pos, ref inbounds));
}
}
return(Vector3.zero);
}
void Update()
{
if (source && source.frames.Count > 0)
{
framenum = Mathf.Clamp(framenum, 0, source.frames.Count - 1);
frame = source.frames[framenum];
float scl = source.Scale * scale;
Vector3 Fshape = Vector3.zero; // Random force due to particle shape
Vector3 Fgrv = new Vector3(0.0f, -Gravity, 0.0f);
float duration = Time.deltaTime;
pos = transform.position;
bool inbounds = true;
float p = density;
float A = Area;
float Re = reynolds;
float coef = 1.0f * p * A * Mathf.Pow(Re, -0.5f);
Vector3 flowpos = pos; //source.transform.worldToLocalMatrix.MultiplyPoint3x4(pos);
// This should be in source already
//Matrix4x4 offtm = Matrix4x4.TRS((frame.size * 0.5f) + frame.offset, Quaternion.identity, Vector3.one);
//Matrix4x4 tm = offtm * source.transform.worldToLocalMatrix;
//Matrix4x4 invtm = tm.inverse;
Vector3 airvel = Vector3.zero;
while (duration > 0.0f)
{
//Vector3 airvel = invtm.MultiplyVector(frame.GetGridVel(tm.MultiplyPoint3x4(flowpos), ref inbounds) * scl);
airvel = frame.GetGridVelWorld(flowpos, ref inbounds) * scl; //invtm.MultiplyVector(frame.GetGridVel(tm.MultiplyPoint3x4(flowpos), ref inbounds) * scl);
if (!inbounds)
{
airvel = new Vector3(scale, 0.0f, 0.0f);
flowpos += vel * dt;
}
else
{
Vector3 tvel = airvel - vel;
float U = tvel.magnitude;
float df = coef * U;
Vector3 dir = tvel.normalized;
Vector3 Fdrag = dir * df;
Vector3 Fp = Fdrag + Fshape + Fgrv;
Vector3 acc = Fp / mass;
vel += acc * dt;
flowpos += vel * dt;
}
duration -= dt;
}
if (flowpos.y < source.floor)
{
flowpos.y = source.floor;
}
transform.position = flowpos; //source.transform.localToWorldMatrix.MultiplyPoint3x4(flowpos);
rot += rotspeed * Time.deltaTime;
Quaternion r = Quaternion.Euler(rot);
Vector3 fdir = flowpos - pos;
switch (align)
{
case MegaFlowAlign.Flow:
{
r = Quaternion.identity;
Quaternion ar = lastalign;
if (airvel != Vector3.zero)
{
ar = Quaternion.LookRotation(airvel) * Quaternion.Euler(alignrot);
}
r = r * ar;
lastalign = ar;
}
break;
case MegaFlowAlign.Object:
{
r = Quaternion.identity;
Quaternion ar = lastalign;
if (fdir != Vector3.zero)
{
ar = Quaternion.LookRotation(fdir) * Quaternion.Euler(alignrot);
}
r = r * ar;
lastalign = ar;
}
break;
}
#if false
if (align)
{
r = Quaternion.identity;
Quaternion ar = lastalign;
if (fdir != Vector3.zero)
{
ar = Quaternion.LookRotation(flowpos - pos) * Quaternion.Euler(alignrot);
}
r = r * ar;
lastalign = ar;
}
#endif
transform.rotation = r; //Quaternion.Euler(r); //ot);
if (usegradient)
{
if (!mat)
{
Renderer rend = GetComponent <Renderer>();
if (rend && rend.material)
{
mat = rend.material;
}
}
if (mat)
{
float spd = airvel.magnitude;
float a = Mathf.Clamp01((spd - speedlow) / (speedhigh - speedlow));
mat.color = gradient.Evaluate(a);
}
}
}
if (rend1 == null)
{
rend1 = GetComponent <Renderer>();
}
if (rend1 && !rend1.enabled)
{
rend1.enabled = true;
}
}
void Update()
{
if ( source && source.frames.Count > 0 )
{
framenum = Mathf.Clamp(framenum, 0, source.frames.Count - 1);
frame = source.frames[framenum];
float scl = source.Scale * scale;
Vector3 Fshape = Vector3.zero; // Random force due to particle shape
Vector3 Fgrv = new Vector3(0.0f, -Gravity, 0.0f);
float duration = Time.deltaTime;
pos = transform.position;
bool inbounds = true;
float p = density;
float A = Area;
float Re = reynolds;
float coef = 1.0f * p * A * Mathf.Pow(Re, -0.5f);
Vector3 flowpos = pos; //source.transform.worldToLocalMatrix.MultiplyPoint3x4(pos);
// This should be in source already
//Matrix4x4 offtm = Matrix4x4.TRS((frame.size * 0.5f) + frame.offset, Quaternion.identity, Vector3.one);
//Matrix4x4 tm = offtm * source.transform.worldToLocalMatrix;
//Matrix4x4 invtm = tm.inverse;
Vector3 airvel = Vector3.zero;
while ( duration > 0.0f )
{
//Vector3 airvel = invtm.MultiplyVector(frame.GetGridVel(tm.MultiplyPoint3x4(flowpos), ref inbounds) * scl);
airvel = frame.GetGridVelWorld(flowpos, ref inbounds) * scl; //invtm.MultiplyVector(frame.GetGridVel(tm.MultiplyPoint3x4(flowpos), ref inbounds) * scl);
if ( !inbounds )
{
airvel = new Vector3(scale, 0.0f, 0.0f);
flowpos += vel * dt;
}
else
{
Vector3 tvel = airvel - vel;
float U = tvel.magnitude;
float df = coef * U;
Vector3 dir = tvel.normalized;
Vector3 Fdrag = dir * df;
Vector3 Fp = Fdrag + Fshape + Fgrv;
Vector3 acc = Fp / mass;
vel += acc * dt;
flowpos += vel * dt;
}
duration -= dt;
}
if ( flowpos.y < source.floor )
flowpos.y = source.floor;
transform.position = flowpos; //source.transform.localToWorldMatrix.MultiplyPoint3x4(flowpos);
rot += rotspeed * Time.deltaTime;
Quaternion r = Quaternion.Euler(rot);
Vector3 fdir = flowpos - pos;
switch ( align )
{
case MegaFlowAlign.Flow:
{
r = Quaternion.identity;
Quaternion ar = lastalign;
if ( airvel != Vector3.zero )
ar = Quaternion.LookRotation(airvel) * Quaternion.Euler(alignrot);
r = r * ar;
lastalign = ar;
}
break;
case MegaFlowAlign.Object:
{
r = Quaternion.identity;
Quaternion ar = lastalign;
if ( fdir != Vector3.zero )
ar = Quaternion.LookRotation(fdir) * Quaternion.Euler(alignrot);
r = r * ar;
lastalign = ar;
}
break;
}
#if false
if ( align )
{
r = Quaternion.identity;
Quaternion ar = lastalign;
if ( fdir != Vector3.zero )
ar = Quaternion.LookRotation(flowpos - pos) * Quaternion.Euler(alignrot);
r = r * ar;
lastalign = ar;
}
#endif
transform.rotation = r; //Quaternion.Euler(r); //ot);
if ( usegradient )
{
if ( !mat )
{
Renderer rend = GetComponent<Renderer>();
if ( rend && rend.material )
mat = rend.material;
}
if ( mat )
{
float spd = airvel.magnitude;
float a = Mathf.Clamp01((spd - speedlow) / (speedhigh - speedlow));
mat.color = gradient.Evaluate(a);
}
}
}
if ( rend1 == null )
rend1 = GetComponent<Renderer>();
if ( rend1 && !rend1.enabled )
rend1.enabled = true;
}
