Exemplo n.º 1
0
func circle2segmentFunc(contacts []*Contact, circle *CircleShape, segment *SegmentShape) int {
	rsum := circle.Radius + segment.Radius

	//Calculate normal distance from segment
	dn := vect.Dot(segment.Tn, circle.Tc) - vect.Dot(segment.Ta, segment.Tn)
	dist := vect.FAbs(dn) - rsum
	if dist > 0.0 {
		return 0
	}

	//Calculate tangential distance along segment
	dt := -vect.Cross(segment.Tn, circle.Tc)
	dtMin := -vect.Cross(segment.Tn, segment.Ta)
	dtMax := -vect.Cross(segment.Tn, segment.Tb)

	// Decision tree to decide which feature of the segment to collide with.
	if dt < dtMin {
		if dt < (dtMin - rsum) {
			return 0
		} else {
			return segmentEncapQuery(circle.Tc, segment.Ta, circle.Radius, segment.Radius, contacts[0], segment.A_tangent)
		}
	} else {
		if dt < dtMax {
			n := segment.Tn
			if dn >= 0.0 {
				n.Mult(-1)
			}
			con := &contacts[0]
			pos := vect.Add(circle.Tc, vect.Mult(n, circle.Radius+dist*0.5))
			(*con).reset(pos, n, dist, 0)
			return 1
		} else {
			if dt < (dtMax + rsum) {
				return segmentEncapQuery(circle.Tc, segment.Tb, circle.Radius, segment.Radius, contacts[0], segment.B_tangent)
			} else {
				return 0
			}
		}
	}
	panic("Never reached")
}
Exemplo n.º 2
0
func Proximity(a, b AABB) vect.Float {
	return vect.FAbs(a.Lower.X+a.Upper.X-b.Lower.X-b.Upper.X) + vect.FAbs(a.Lower.Y+a.Upper.Y-b.Lower.Y-b.Upper.Y)
}
Exemplo n.º 3
0
func (S1 *Segment) Intersects(S2 *Segment) bool {
	u := vect.Sub(S1.Point2, S1.Point1)
	v := vect.Sub(S2.Point2, S2.Point1)
	w := vect.Sub(S1.Point1, S2.Point1)
	D := vect.Cross(u, v)

	// test if  they are parallel (includes either being a point)
	if vect.FAbs(D) < 0.0000001 { // S1 and S2 are parallel
		if vect.Cross(u, w) != 0 || vect.Cross(v, w) != 0 {
			return false // they are NOT collinear
		}
		// they are collinear or degenerate
		// check if they are degenerate  points
		du := vect.Dot(u, u)
		dv := vect.Dot(v, v)
		if du == 0 && dv == 0 { // both segments are points
			if !vect.Equals(S1.Point1, S2.Point1) { // they are distinct  points
				return false
			}
			return true
		}
		if du == 0 { // S1 is a single point
			if !S2.Contains(S1.Point1) { // but is not in S2
				return false
			}
			return true
		}
		if dv == 0 { // S2 a single point
			if !S1.Contains(S2.Point1) { // but is not in S1
				return false
			}
			return true
		}
		// they are collinear segments - get  overlap (or not)
		var t0, t1 vect.Float // endpoints of S1 in eqn for S2
		w2 := vect.Sub(S1.Point2, S2.Point1)
		if v.X != 0 {
			t0 = w.X / v.X
			t1 = w2.X / v.X
		} else {
			t0 = w.Y / v.Y
			t1 = w2.Y / v.Y
		}
		if t0 > t1 { // must have t0 smaller than t1
			t0, t1 = t1, t0 // swap if not
		}
		if t0 > 1 || t1 < 0 {
			return false // NO overlap
		}
		return true
	}

	// the segments are skew and may intersect in a point
	// get the intersect parameter for S1
	sI := vect.Cross(v, w) / D
	if sI < 0 || sI > 1 { // no intersect with S1
		return false
	}
	// get the intersect parameter for S2
	tI := vect.Cross(u, w) / D
	if tI < 0 || tI > 1 { // no intersect with S2
		return false
	}
	return true
}