Exemplo n.º 1
0
// Find the closest point on a line (or segment) to a point.
uint32_t plClosest::PointOnLine(const hsPoint3& p0,
                  const hsPoint3& p1, const hsVector3& v1,
                  hsPoint3& cp,
                  uint32_t clamp)
{
    float invV1Sq = v1.MagnitudeSquared();
    // v1 is also zero length. The two input points are the only options for output.
    if( invV1Sq < kRealSmall )
    {
        cp = p1;
        return kClamp;
    }
    float t = v1.InnerProduct(p0 - p1) / invV1Sq;
    cp = p1;
    // clamp to the ends of segment v1.
    if( (clamp & kClampLower1) && (t < 0) )
    {
        return kClampLower1;
    }
    if( (clamp & kClampUpper1) && (t > 1.f) )
    {
        cp += v1;
        return kClampUpper1;
    }

    cp += v1 * t;
    return 0;
}
Exemplo n.º 2
0
bool plTriUtils::ProjectOntoPlane(const hsVector3& norm, float dist, hsPoint3& p)
{
    float normMagSq = norm.MagnitudeSquared();
    if( normMagSq > kAlmostZero )
    {
        dist /= normMagSq;

        p += norm * dist;

        return true;
    }
    return false;
}
Exemplo n.º 3
0
// Find closest points to each other from two lines (or segments).
uint32_t plClosest::PointsOnLines(const hsPoint3& p0, const hsVector3& v0, 
                  const hsPoint3& p1, const hsVector3& v1,
                  hsPoint3& cp0, hsPoint3& cp1,
                  uint32_t clamp)
{
    float invV0Sq = v0.MagnitudeSquared();
    // First handle degenerate cases.
    // v0 is zero length. Resolves to finding closest point on p1+v1 to p0
    if( invV0Sq < kRealSmall )
    {
        cp0 = p0;
        return kClamp0 | PointOnLine(p0, p1, v1, cp1, clamp);
    }
    invV0Sq = 1.f / invV0Sq;

    // The real thing here, two non-zero length segments. (v1 can
    // be zero length, it doesn't affect the math like |v0|=0 does,
    // so we don't even bother to check. Only means maybe doing extra
    // work, since we're using segment-segment math when all we really
    // need is point-segment.)

    // The parameterized points for along each of the segments are
    // P(t0) = p0 + v0*t0
    // P(t1) = p1 + v1*t1
    //
    // The closest point on p0+v0 to P(t1) is:
    //  cp0 = p0 + ((P(t1) - p0) dot v0) * v0 / ||v0||  ||x|| is mag squared here
    //  cp0 = p0 + v0*t0 => t0 = ((P(t1) - p0) dot v0 ) / ||v0||
    //                      t0 = ((p1 + v1*t1 - p0) dot v0) / ||v0||
    //
    //  The distance squared from P(t1) to cp0 is:
    //  (cp0 - P(t1)) dot (cp0 - P(t1))
    //
    //  This expands out to:
    //
    //  CV0 dot CV0 + 2 CV0 dot DV0 * t1 + (DV0 dot DV0) * t1^2
    //
    //  where
    //
    //  CV0 = p0 - p1 + ((p1 - p0) dot v0) / ||v0||) * v0 == vector from p1 to closest point on p0+v0
    //  and
    //  DV0 = ((v1 dot v0) / ||v0||) * v0 - v1 == ortho divergence vector of v1 from v0 negated.
    //
    //  Taking the first derivative to find the local minimum of the function gives
    //
    //  t1 = - (CV0 dot DV0) / (DV0 dot DV0)
    //  and
    //  t0 = ((p1 - v1 * t1 - p0) dot v0) / ||v0|| 
    //
    // which seems kind of obvious in retrospect.

    hsVector3 p0subp1(&p0, &p1);

    hsVector3 CV0 = p0subp1;
    CV0 += v0 * p0subp1.InnerProduct(v0) * -invV0Sq;
    
    hsVector3 DV0 = v0 * (v1.InnerProduct(v0) * invV0Sq) - v1;
    
    // Check for the vectors v0 and v1 being parallel, in which case
    // following the lines won't get us to any closer point.
    float DV0dotDV0 = DV0.InnerProduct(DV0);
    if( DV0dotDV0 < kRealSmall )
    {
        // If neither is clamped, return any two corresponding points.
        // If one is clamped, return closest points in its clamp range.
        // If both are clamped, well, both are clamped. The distance between
        //      points will no longer be the distance between lines.
        // In any case, the distance between the points should be correct.
        uint32_t clamp1 = PointOnLine(p0, p1, v1, cp1, clamp);
        uint32_t clamp0 = PointOnLine(cp1, p0, v0, cp0, clamp >> 1);
        return clamp1 | (clamp0 << 1);
    }
Exemplo n.º 4
0
plTriUtils::Bary plTriUtils::IComputeBarycentric(const hsVector3& v12, float invLenSq12, const hsVector3& v0, const hsVector3& v1, hsPoint3& out)
{
    uint32_t  state = 0;

    float lenSq0 = v0.MagnitudeSquared();
    if( lenSq0 < kAlmostZeroSquared )
    {
        // On edge p1-p2;
        out[0] = 0;
        state |= kOnEdge12;
    }
    else
    {
        out[0] = lenSq0 * invLenSq12;
        out[0] = sqrt(out[0]);
        // 
        if( v0.InnerProduct(v12) < 0 )
        {
            out[0] = -out[0];
            state |= kOutsideTri;
        }
        else if( out[0] > kPastOne )
            state |= kOutsideTri;
        else if( out[0] > kAlmostOne )
            state |= kOnVertex0;
    }
    
    float lenSq1 = v1.MagnitudeSquared();
    if( lenSq1 < kAlmostZeroSquared )
    {
        // On edge p0-p2
        out[1] = 0;
        state |= kOnEdge02;
    }
    else
    {
        out[1] = lenSq1 * invLenSq12;
        out[1] = sqrt(out[1]);

        if( v1.InnerProduct(v12) < 0 )
        {
            out[1] = -out[1];
            state |= kOutsideTri;
        }
        else if( out[1] > kPastOne )
            state |= kOutsideTri;
        else if( out[1] > kAlmostOne )
            state |= kOnVertex1;
    }

    // Could make more robust against precision problems
    // by repeating above for out[2], then normalizing
    // so sum(out[i]) = 1.f
    out[2] = 1.f - out[0] - out[1];

    if( out[2] < kPastZero )
        state |= kOutsideTri;
    else if( out[2] < kAlmostZero )
        state |= kOnEdge01;
    else if( out[2] > kAlmostOne )
        state |= kOnVertex2;

    /*
    if( a,b,c outside range [0..1] )
        p is outside tri;
    else if( a,b,c == 1 )
        p is on vert;
    else if( a,b,c == 0 )
        p is on edge;
    */

    if( state & kOutsideTri )
        return kOutsideTri;

    if( state & kOnVertex )
        return Bary(state & kOnVertex);

    if( state & kOnEdge )
        return Bary(state & kOnEdge);

    return kInsideTri;
}