Difference between revisions of "Geometric"

Latest revision as of 21:00, 24 January 2015

Please vote for: https://jira.secondlife.com/browse/WEB-235 So that I can expand each function into deeper detail without the page starting to fail in readability. --Nexii Malthus 23:05, 24 October 2008 (UTC)

:Break it up so each major section has its own page... thats why hypertext was invented. -Overbrain Unplugged 13:36, 10 October 2010 (UTC)

Geometric Library

Line Functions

Line and Point, Vector

Calculates the vector from a point 'to' the closest point on a line

vector gLXdV(vector O,vector D,vector A){
    return (O-A)-((O-A)*D)*D;}

Input	Description
vector O	Origin of Line
vector D	Direction of Line
vector A	Origin of Point
Output	Description
return vector gLXdV	Returns origin of closest point on Line to Point

3D

By Nexii Malthus

Line and Point, Distance

Calculates distance of line to point, same as measuring magnitude of Line and Point Vector, but faster on it's own

float gLXdZ(vector O,vector D,vector A){
    vector k = ( A - O ) % D;
    return llSqrt( k * k );}

Input	Description
vector O	Origin of Line
vector D	Direction of Line (unit vector)
vector A	Origin of Point
Output	Description
return float gLXdZ	Returns numerical distance from Line to Point

3D

By Nexii Malthus

Line Nearest Point, Nearest Point

Returns nearest point on line to given point

vector gLXnX(vector O,vector D,vector A){
    return gLXdV(O,D,A) + A;}

Input	Description
vector O	Origin of Line
vector D	Direction of Line
vector A	Origin of Point
Output	Description
return vector gLXnX	Returns nearest point on line given point
Requirement
function vector gLXdV(vector O,vector D,vector A)

3D

By Nexii Malthus

Line and Line, Vector

Shortest vector of two lines

vector gLLdV(vector O1,vector D1,vector O2,vector D2){
    vector A = O2 - O1; vector B = D1 % D2;
    return B*( (A*B)/(B*B) );}

Input	Description
vector O1	Origin of Line 1
vector D1	Direction of Line 1
vector O2	Origin of Line 2
vector D2	Direction of Line 2
Output	Description
return vector gLLdV	Returns shortest vector between the two lines

3D

By Nexii Malthus

Line and Line, Distance

Returns the distance between two lines

float gLLdZ(vector O1,vector D1,vector O2,vector D2){
    vector A = D1%D2;float B = llVecMag(A);A = <A.x/B,A.y/B,A.z/B>;
    return (O2-O1) * A;}

Input	Description
vector O1	Origin of Line 1
vector D1	Direction of Line 1
vector O2	Origin of Line 2
vector D2	Direction of Line 2
Output	Description
return float gLLdZ	Returns numerical distance between the two lines

3D

By Nexii Malthus

Line and Line, Nearest point

Closest point of two lines

vector gLLnX(vector O1,vector D1,vector O2,vector D2){
    vector nO1 = < O1*D1, O1*D2, 0>;
    vector nO2 = < O2*D1, O2*D2, 0>;
    vector nD1 = < D1*D1, O1*D2, 0>;
    vector nD2 = < O2*D1, O2*D2, 0>;
    
    float t = ( nD2.x*nD1.y - nD1.x*nD2.y );
    
    t = ( nD2.y*(nO1.x-nO2.x) - nD2.x*(nO1.y-nO2.y) ) / t;
    
    return O1 + D1*t;}

Input	Description
vector O1	Origin of Line 1
vector D1	Direction of Line 1
vector O2	Origin of Line 2
vector D2	Direction of Line 2
Output	Description
return vector gLLnX	Returns closest point between the two lines

2D

By Nexii Malthus

Line and Line, intersection point

Computes intersection point of two lines, if there is any, else <-1,-1,-1> if none.

vector gLLxX( vector A, vector B, vector C, vector D ){
    vector b = B-A; vector d = D-C;
    float dotperp = b.x*d.y - b.y*d.x;
    if (dotperp == 0) return <-1,-1,-1>;
    vector c = C-A;
    float t = (c.x*d.y - c.y*d.x) / dotperp;
    return <A.x + t*b.x, A.y + t*b.y, 0>;}

Input	Description
vector A	Start of Line 1
vector B	End of Line 1
vector C	Start of Line 2
vector D	End of Line 2
Output	Description
return vector gLLxX	The intersection point of the two lines, else <-1,-1,-1> if none

2D

By Nexii Malthus

Line and Line, two nearest points of lines

Two closest points of two lines on each line

vector X1;vector X2;
gLLnnXX(vector O1,vector D1,vector O2,vector D2){
    vector nO1 = < O1*D1, O1*D2, 0>;
    vector nO2 = < O2*D1, O2*D2, 0>;
    vector nD1 = < D1*D1, O1*D2, 0>;
    vector nD2 = < O2*D1, O2*D2, 0>;
    
    float t = ( nD2.x*nD1.y - nD1.x*nD2.y );
    
    t = ( nD2.y*(nO1.x-nO2.x) - nD2.x*(nO1.y-nO2.y) ) / t;
    
    X1 = O1 + D1*t;
    X2 = X1 + nD1%nD2;}

Input	Description
vector O1	Origin of Line 1
vector D1	Direction of Line 1
vector O2	Origin of Line 2
vector D2	Direction of Line 2
Output	Description
vector X1	Closest point on line 1 to line 2
vector X2	Closest point on line 2 to line 1
Requirement
global vector X1
global vector X2

2D

By Nexii Malthus

Line and Line, nearest line

Input two lines, the function will return a list containing two vectors responding to the line nearest between them. As well as two floats corresponding to the scalar value on the two line of where the line has an end located at.

list gLLnL( vector v0, vector v1, vector v2, vector v3 ) {
    float Eps = 0.000001; vector vx; vector vy; vector va; vector vb; vector vc;
    float x; float y; float d0; float d1; float d2; float d3; float d4;
    va = v0-v2; vb = v3-v2; if(llVecMag(vb)<Eps) return [];
    vc = v1-v0; if(llVecMag(vc)<Eps) return [];
    d0 = va*vb; d1 = vb*vc; d2 = va*vc; d3 = vb*vb; d4 = vc*vc;
    float den = d4*d3-d1*d1; if( llFabs(den) < Eps ) return [];
    float num = d0*d1-d2*d3; x = num/den; y = (d0+d1*x)/d3;
    vx = v0+vc*x; vy = v2+vb*y; return [vx,vy,x,y]; }

Input	Description
vector v0	Point on Line 1
vector v1	Point on Line 1
vector v2	Point on Line 2
vector v3	Point on Line 2
Output	Description
[vx]	Nearest point on Line 1 to Line 2
[vy]	Nearest point on Line 2 to Line 1
[x]	Scalar value representing location of vx on line 1 (range [v0,v1])
[y]	Scalar value representing location of vy on line 2 (range [v2,v3])

3D

By Nexii Malthus

Line and Line Segments, nearest line segment

Input two line segments, the function will return a list containing two vectors responding to the line segment nearest between them. As well as two floats corresponding to the scalar value on the two line segments of where the line segment has an end located at.

list gLSLSnLS( vector v0, vector v1, vector v2, vector v3 ) {
    float Eps = 0.000001; vector vx; vector vy; vector va; vector vb; vector vc;
    float x; float y; float d0; float d1; float d2; float d3; float d4;
    va = v0-v2; vb = v3-v2; if(llVecMag(vb)<Eps) return [];
    vc = v1-v0; if(llVecMag(vc)<Eps) return [];
    if( llFabs(vc.x + vc.y + vc.z) < Eps ) return [];
    d0 = va*vb; d1 = vb*vc; d2 = va*vc; d3 = vb*vb; d4 = vc*vc;
    float den = d4*d3-d1*d1; if( llFabs(den) < Eps ) return [];
    float num = d0*d1-d2*d3; x = num/den; y = (d0+d1*x)/d3;
    if(x<0)x=0; else if(x>1)x=1; if(y<0)y=0; else if(y>1)y=1;
    vx = v0+vc*x; vy = v2+vb*y; return [vx,vy,x,y]; }

Input	Description
vector v0	Start of Line Segment 1
vector v1	End of Line Segment 1
vector v2	Start of Line Segment 2
vector v3	End of Line Segment 2
Output	Description
[vx]	Nearest point on Line Segment 1 to Line Segment 2
[vy]	Nearest point on Line Segment 2 to Line Segment 1
[x]	Scalar value representing location of vx on Line Segment 1 (range [v0,v1])
[y]	Scalar value representing location of vy on Line Segment 2 (range [v2,v3])

3D

By Nexii Malthus

Line and Line, two nearest points with vector and distance

Computes two closest points of two lines, vector and distance

vector X1;vector X2;vector V1;float Z1;
gLLnnXXVZ(vector O1,vector D1,vector O2,vector D2){
    vector nO1 = < O1*D1, O1*D2, 0>;
    vector nO2 = < O2*D1, O2*D2, 0>;
    vector nD1 = < D1*D1, O1*D2, 0>;
    vector nD2 = < O2*D1, O2*D2, 0>;
    
    float t = ( nD2.x*nD1.y - nD1.x*nD2.y );
    
    t = ( nD2.y*(nO1.x-nO2.x) - nD2.x*(nO1.y-nO2.y) ) / t;
    
    X1 = O1 + D1*t;
    X2 = X1 + CP(nD1,nD2);
    V1 = nD1%nD2;
    Z1 = llVecMag(V1);}

Input	Description
vector O1	Origin of Line 1
vector D1	Direction of Line 1
vector O2	Origin of Line 2
vector D2	Direction of Line 2
Output	Description
vector X1	Closest point on line 1 to line 2
vector X2	Closest point on line 2 to line 1
vector V1	Direction vector of line 1 to line 2
float Z1	Numerical distance of line 1 to line 2
Requirement
global vector X1
global vector X2
global vector V1
global float Z1

2D

By Nexii Malthus

Line and Point, Direction

Works out where point (X) is relative to the line of the segment (L0, L1).

float gLSPdir( vector L0, vector L1, vector X ){
    return (L1.x - L0.x)*(X.y - L0.y) - (X.x - L0.x)*(L1.y - L0.y);
}

Input	Description
vector L0, vector L1	Start and End of line segment
vector X	Origin of Point
Output	Description
float isLeft( vector L0, vector L1, vector X )	Returns float, >0 is Left, 0 on Line, <0 is Right, according to line angle

2D

Plane Functions

Plane and Point, Distance

Finds distance of a point from a plane

float gPXdZ(vector Pn,float Pd,vector A){
    return A * Pn + Pd;}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector A	Origin of Point
Output	Description
return float gPXdZ	Returns Distance between plane and point

3D

By Nexii Malthus

Plane and Point, Vector

Finds vector that points from point to nearest on plane

vector gPXdV(vector Pn,float Pd,vector A){
    return -(Pn * A + Pd)*Pn;}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector A	Origin of Point
Output	Description
return vector gPXdV	Returns vector from point to closest point on plane

3D

By Nexii Malthus

Plane and Point, Nearest point

Finds closest point on plane given point

vector gPXnX(vector Pn,float Pd,vector A){
    return A - (Pn * A + Pd) * Pn;}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector A	Origin of Point
Output	Description
return vector gPXnX	Returns vector of a point from closest of point to plane

3D

By Nexii Malthus

Plane and Ray, Intersection Distance

Finds distance to intersection of plane along ray

float gPRxZ(vector Pn,float Pd,vector O,vector D){
    return -((Pn*O+Pd)/(Pn*D));}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector O	Origin of Ray
vector D	Direction of Ray
Output	Description
return float gPRxZ	Returns float distance of intersection between ray and plane

3D

By Nexii Malthus

Plane and Ray, Vector

Finds distance vector along a ray to a plane

vector gPRdV(vector Pn,float Pd,vector O,vector D){
    return D * gPRxZ(Pn,Pd,O,D);}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector O	Origin of Ray
vector D	Direction of Ray
Output	Description
return vector gPRdV	Returns vector along a ray to a plane
Requirement
function float gPRxZ(vector Pn,float Pd,vector O,vector D)

3D

By Nexii Malthus

Plane and Ray, Intersection Point

Finds intersection point along a ray to a plane

vector gPRxX(vector Pn,float Pd,vector O,vector D){
    return O + gPRdV(Pn,Pd,O,D);}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector O	Origin of Ray
vector D	Direction of Ray
Output	Description
return vector gPRxX	Returns vector point of intersection between ray and plane
Requirement
function vector gPRdV(vector Pn,float Pd,vector O,vector D)

3D

By Nexii Malthus

Plane and Line, Intersection Point

Finds interesection point of a line and a plane

vector gPLxX(vector Pn,float Pd,vector O,vector D){
    return O + D*-( (Pn*O-Pd)/(Pn*D) );}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector O	Origin of Line
vector D	Direction of Line
Output	Description
return vector gPLxX	Returns vector point of intersection between line and plane

3D

By Nexii Malthus

Plane and Plane, Intersection Line

Finds line of intersection of two planes

vector oO;vector oD;

gPPxL(vector Pn,float Pd,vector Qn,float Qd){
    oD = (Pn%Qn)/llVecMag(Pn%Qn);
    vector Cross = (Pn%Qn)%Pn;
    vector Bleh = (-Pd*Pn);
    oO = Bleh - (Qn*Cross)/(Qn*Bleh+Qd)*Cross/llVecMag(Cross);}

Input	Description
vector Pn	Normal of Plane 1 (unit vector)
float Pd	Distance of Plane 1
vector Qn	Normal of Plane 2 (unit vector)
float Qd	Distance of Plane 2
Output	Description
vector oO	Intersection Line's origin
vector oD	Intersection Line's direction
Requirement
global vector oO
global vector oD

3D

By Nexii Malthus

Plane and Ray, Projection

Projects a ray onto a plane

vector oO;vector oD;

gPRpR(vector Pn,float Pd,vector O,vector D){
    oO = O - (Pn * O + Pd) * Pn;
    vector t = llVecNorm( D - (Pn*((D*Pn)/(Pn*Pn))) );t = <1.0/t.x,1.0/t.y,1.0/t.z>;
    oD = Pn%t;}

Input	Description
vector Pn	Normal of Plane (unit vector)
float Pd	Distance of Plane
vector O	Origin of Ray
vector D	Direction of Ray
Output	Description
vector oO	Projected Ray Origin
vector oD	Projected Ray Direction
Requirement
global vector oO
global vector oD

3D

By Nexii Malthus

Sphere Functions

Sphere and Ray, Intersection Point

Finds intersection point of sphere and ray

vector gSRxX(vector Sp, float Sr, vector Ro, vector Rd){
    float t; Ro -= Sp;
    if(Rd == ZERO_VECTOR) return ZERO_VECTOR;
    
    float a = Rd * Rd;
    float b = 2 * Rd * Ro;
    float c = (Ro * Ro)  - (Sr * Sr);
    
    float disc = b * b - 4 * a * c;
    
    if(disc < 0) return ZERO_VECTOR;
    
    float distSqrt = llSqrt(disc);
    float q;
    
    if(b < 0)
        q = (-b - distSqrt)/2.0;
    else 
        q = (-b + distSqrt)/2.0;
    
    float t0 = q / a;
    float t1 = c / q;
    
    if(t0 > t1){
        float temp = t0;
        t0 = t1;
        t1 = temp;
    }
    
    if(t1 < 0) return ZERO_VECTOR;
    
    if(t0 < 0)
        t = t1;
    else
        t = t0;
    
    return Sp + Ro + (t * Rd);
}

Input	Description
vector Sp	Origin of Sphere
float Sr	Radius of Sphere
vector Ro	Origin of Ray
vector Rd	Direction of Ray
Output	Description
vector gSRxX	Returns intersection point of sphere and ray otherwise ZERO_VECTOR

3D

By Nexii Malthus

Sphere and Ray, Intersection Boolean

Finds if there is a intersection of sphere and ray

integer gSRx(vector Sp, float Sr, vector Ro, vector Rd){
    float t;Ro = Ro - Sp;
    //vector RayOrg = llDetectedPos(x) - llGetPos();
    if(Rd == ZERO_VECTOR) return FALSE;
    
    float a = Rd * Rd;
    float b = 2 * Rd * Ro;
    float c = (Ro * Ro)  - (Sr * Sr);
    
    float disc = b * b - 4 * a * c;
    
    if(disc < 0) return FALSE;
    return TRUE;
}

Input	Description
vector Sp	Origin of Sphere
float Sr	Radius of Sphere
vector Ro	Origin of Ray
vector Rd	Direction of Ray
Output	Description
integer gSRx	Returns a boolean indicating if there is a valid intersection

3D

By Nexii Malthus

Ray Functions

Ray and Point, projected distance

Finds projected distance of a point along a ray

float gRXpZ(vector O,vector D,vector A){
    return (A-O)*D;}

Input	Description
vector O	Origin of Ray
vector D	Direction of Ray
vector A	Origin of Point
Output	Description
float gRXpZ	Returns projected distance of a point along a ray

3D

By Nexii Malthus

Box Functions

Box and Ray, Intersection Distance

Finds intersection of a Ray to a Box and returns intersection distance, otherwise -1 if there is no legal intersection.

float gBRxZ(vector Ro,vector Rd, vector Bo, vector Bs, rotation Br){
    vector oB = (Ro-Bo)/Br;    vector dB = Rd/Br;    vector eB = 0.5*Bs;
    float mD = -1.0;    float D;    vector X;
    
    if(llFabs(dB.x) > 0.000001){
        D = (-eB.x - oB.x ) / dB.x;
        if(D >= 0.0){
            X = oB + D * dB;
            if(X.y >= -eB.y && X.y <= eB.y && X.z >= -eB.z && X.z <= eB.z)
                mD = D;
        }
        D = ( eB.x - oB.x ) / dB.x;
        if (D >= 0.0){
            X = oB + D * dB;
            if(X.y >= -eB.y && X.y <= eB.y && X.z >= -eB.z && X.z <= eB.z) 
                if (mD < 0.0 || mD > D)
                    mD = D;
        }
    }
    
    if(llFabs(dB.y) > 0.000001){
        D = (-eB.y - oB.y ) / dB.y;
        if(D >= 0.0){
            X = oB + D * dB;
            if(X.x >= -eB.x && X.x <= eB.x && X.z >= -eB.z && X.z <= eB.z)
                if (mD < 0.0 || mD > D)
                    mD = D;
        }
        D = ( eB.y - oB.y ) / dB.y;
        if (D >= 0.0){
            X = oB + D * dB;
            if(X.x >= -eB.x && X.x <= eB.x && X.z >= -eB.z && X.z <= eB.z)
                if (mD < 0.0 || mD > D)
                    mD = D;
        }
    }
    
    if(llFabs(dB.z) > 0.000001){
        D = (-eB.z - oB.z ) / dB.z;
        if(D >= 0.0){
            X = oB + D * dB;
            if(X.x >= -eB.x && X.x <= eB.x && X.y >= -eB.y && X.y <= eB.y)
                if (mD < 0.0 || mD > D)
                    mD = D;
        }
        D = ( eB.z - oB.z ) / dB.z;
        if (D >= 0.0){
            X = oB + D * dB;
            if(X.x >= -eB.x && X.x <= eB.x && X.y >= -eB.y && X.y <= eB.y)
                if (mD < 0.0 || mD > D)
                    mD = D;
        }
    }
    
    return mD;
}

Input	Description
vector Ro	Origin of Ray
vector Rd	Direction of Ray
vector Bo	Origin of Box
vector Bs	Size of Box
rotation Br	Rotation of Box
Output	Description
float gBRxZ	Returns distance to intersection of a ray and a box

3D

By Hewee Zetkin

Box and Ray, Intersection Point

Finds intersection of a Ray to a Box and returns intersection point, otherwise ZERO_VECTOR if there is no legal intersection.

vector gBRxX( vector Ro, vector Rd, vector Bo, vector Bs, rotation Br){
    float k = gBRxZ(Ro,Rd,Bo,Bs,Br);
    if( k != -1.0 ) return Ro + Rd * k;
    else return ZERO_VECTOR;}

Input	Description
vector Ro	Origin of Ray
vector Rd	Direction of Ray
vector Bo	Origin of Box
vector Bs	Size of Box
rotation Br	Rotation of Box
Output	Description
vector gBRxX	Returns point of intersection of a ray and a box
Requirement
float gBRxZ(vector Ro,vector Rd, vector Bo, vector Bs, rotation Br)

3D

By Hewee Zetkin

Box and Point, Intersection Boolean

Finds if there is an intersection of a Point and a Box and returns boolean

integer gBXx(vector A, vector Bo, vector Bs, rotation Br){
    vector eB = 0.5*Bs; vector rA = (A-Bo)/Br;
    return (rA.x<eB.x && rA.x>-eB.x && rA.y<eB.y && rA.y>-eB.y && rA.z<eB.z && rA.z>-eB.z); }

Input	Description
vector A	Origin of Point
vector Bo	Origin of Box
vector Bs	Size of Box
rotation Br	Rotation of Box
Output	Description
integer gBXx(vector A, vector Bo, vector Bs, rotation Br)	Returns boolean check of intersection of a point and a box if there is one, otherwise FALSE

3D

By Nexii Malthus

Box and Point, Nearest Point on Edge

Processes point on nearest edge of box to given point

vector gBXnEX(vector A, vector Bo, vector Bs, rotation Br){
    vector eB = 0.5*<llFabs(Bs.x),llFabs(Bs.y),llFabs(Bs.z)>;
    vector rA = (A-Bo)/Br;
    
    float mD = 3.402823466E+38;
    vector X;
    list EdgesX = [< 0, eB.y, eB.z>, < 0,-eB.y, eB.z>, < 0,-eB.y,-eB.z>, < 0, eB.y,-eB.z>];
    list EdgesY = [< eB.x, 0, eB.z>, <-eB.x, 0, eB.z>, <-eB.x, 0,-eB.z>, < eB.x, 0,-eB.z>];
    list EdgesZ = [< eB.x, eB.y, 0>, <-eB.x, eB.y, 0>, <-eB.x,-eB.y, 0>, < eB.x,-eB.y, 0>];
    
    integer x = (EdgesX != []);
    while( x-- ){
        float y = gLXdZ( llList2Vector( EdgesX, x ), <1,0,0>, rA );
        
        if( rA.x > eB.x ) y += rA.x - eB.x;
        else if( rA.x < -eB.x ) y -= rA.x - -eB.x;
        
        if( y < mD ){ mD = y; X = gLXnX( llList2Vector( EdgesX, x ), <1,0,0>, rA ); }
    }
    x = (EdgesY != []);
    while( x-- ){
        float y = gLXdZ( llList2Vector( EdgesY, x ), <0,1,0>, rA );
        
        if( rA.y > eB.y ) y += rA.y - eB.y;
        else if( rA.y < -eB.y ) y -= rA.y - -eB.y;
        
        if( y < mD ){ mD = y; X = gLXnX( llList2Vector( EdgesY, x ), <0,1,0>, rA ); }
    }
    x = (EdgesZ != []);
    while( x-- ){
        float y = gLXdZ( llList2Vector( EdgesZ, x ), <0,0,1>, rA );
        
        if( rA.z > eB.z ) y += rA.z - eB.z;
        else if( rA.z < -eB.z ) y -= rA.z - -eB.z;
        
        if( y < mD ){ mD = y; X = gLXnX( llList2Vector( EdgesZ, x ), <0,0,1>, rA ); }
    }
    
    if( mD < 0.000001 ) return <-1,-1,-1>;
    if(      X.x >  eB.x ) X.x =  eB.x;
    else if( X.x < -eB.x ) X.x = -eB.x;
    if(      X.y >  eB.y ) X.y =  eB.y;
    else if( X.y < -eB.y ) X.y = -eB.y;
    if(      X.z >  eB.z ) X.z =  eB.z;
    else if( X.z < -eB.z ) X.z = -eB.z;
    
    return Bo + ( X * Br );}

Input	Description
vector A	Origin of Point
vector Bo	Origin of Box
vector Bs	Size of Box
rotation Br	Rotation of Box
Output	Description
vector gBXnEX(vector A, vector Bo, vector Bs, rotation Br)	Returns nearest point on edge of box B closest to point A. Returns <-1,-1,-1> if already on closest point.
Requirement
float gLXdZ(vector O,vector D,vector A)
vector gLXdV(vector O,vector D,vector A)
vector gLXnX(vector O,vector D,vector A)

3D

By Nexii Malthus

Cylinder

Cylinder and Point, Intersection Boolean

Finds if there is an intersection of a Point and a Cylinder and returns boolean

integer gCXx( vector A, vector O, rotation R, vector S ) {
    A = ( A - O ) / R;// Converts to local object frame
    return (llPow(A.x/S.x*2,2) + llPow(A.y/S.y*2,2)) <= 1. // Test radius
        && llFabs(A.z/S.z*2) <= 1.;// Test top/bottom
}

Input	Description
vector A	Origin of Point
vector Bo	Origin of Cylinder
vector Bs	Size of Cylinder
rotation Br	Rotation of Cylinder
Output	Description
integer gCXx( vector A, vector O, rotation R, vector S )	Returns boolean check of intersection of a point and a cylinder if there is one, otherwise FALSE

3D

By Nexii Malthus

Polygon

Polygon and Point, Intersection Boolean

Figures out if point is inside of polygon or otherwise.

integer gCPXx( list CP, vector X )
{//Copyright (c) 1970-2003, Wm. Randolph Franklin; 2008, Strife Onizuka
    integer i = ~(CP != []);
    integer c = 0;
    if(i < -2){
        vector vi = llList2Vector(CP, -1);
        do {
            vector vj = vi;
            vi = llList2Vector(CP, i);
            if((vi.y > X.y) ^ (vj.y > X.y)){
                if(vj.y != vi.y)
                    c = c ^ (X.x < (((vj.x - vi.x) * (X.y - vi.y) / (vj.y - vi.y)) + vi.x));
                else c = c ^ (0 < ((vj.x-vi.x) * (X.y-vi.y)));
            }
        } while (++i);
    }
    return c;
}

Input	Description
list CP	Vertices of Concave Polygon
vector X	Origin of Point
Output	Description
integer gCPXx( list CP, vector X )	Returns TRUE if point (X) intersects concave polygon (CP), otherwise FALSE

2D

Polygon and Line Segment, Intersection Boolean

Figures out if line segment intersects with polygon.

integer gVPLSx( vector P0, vector P1, list VP ){
    //Copyright 2001, softSurfer (www.softsurfer.com); 2008, Nexii Malthus
    if( P0 == P1 ) return gCPXx( VP, P0 );
    float tE = 0; float tL = 1;
    float t; float N; float D;
    vector dS = P1 - P0;
    vector e; integer x; integer y = VP!=[];
    @start;
    for( x = 0; x < y; ++x ){
        e = llList2Vector( VP, x+1 ) - llList2Vector( VP, x );
        N = Perp( e, P0 - llList2Vector( VP, x ) );
        D = -Perp( e, dS );
        if( llFabs(D) < 0.00000001 )
            if( N < 0 ) return FALSE;
            else jump start;
        t = N / D;
        if( D < 0 ){
            if( t > tE ){   tE = t; if( tE > tL ) return FALSE;     }
        } else {
            if( t < tL ){   tL = t; if( tL < tE ) return FALSE;     }
    }   }
    // PointOfEntrance = P0 + tE * dS;
    // PointOfExit = P0 + tL * dS;
    return TRUE;
}

Input	Description
list VP	Vertices of Convex Polygon
vector P0, vector P1	Start and End of Line Segment
Output	Description
integer gVPLSx( vector P0, vector P1, list VP )	Returns TRUE if line segment (P0,P1) intersects convex polygon (VP), otherwise FALSE
Requirement
float Perp( vector U, vector V ){ return U.xV.y - U.yV.x; }	Perpendicular dot product
integer gCPXx( list CP, vector X )	Only needed for (P0 == P1) safety catch check, so optional

2D

Other Functions

3D Projection

Projects a vector A by vector B.

vector Project3D(vector A,vector B){
    return B * ( ( A * B ) / ( B * B ) );}

Input	Description
vector A	First Vector
vector B	Second Vector
Output	Description
return Project3D(vector A, vector B)	Returns result of projection

3D

By Nexii Malthus

Reflection

Reflects Ray R with surface normal N

vector Reflect(vector R,vector N){
    return R - 2 * N * ( R * N );}

Input	Description
vector R	Ray Normal
vector N	Surface Normal
Output	Description
return Reflect(vector R, vector N)	Returns result of reflection

3D

By Nexii Malthus

Glossary

For anyone curious to the shorthand used and who wish to use a lookup table can use this as a reference. Or anyone who wishes to add a new function to the library is welcome to but it would be recommended to keep consistency. I tried to minimize the script function names to be easily readable. All the geometric function names start with a g.

g (Shape1) (Shape2) (Process) (Return (Only needed if other than integer))

Here is the legend:

Shorthand	Name	Description
Geometric Types, all the shapes in the library
X	Point	vector defining a point in space
L	Line	A line has an origin and a direction and is infinitely long
LS	Line Segment	A line segment is a finite line and therefore consists of a start and end position
R	Ray	A ray is like a line, except it is more distinct as it defines wether it points forward or back
P	Plane	A 2D doubly ruled surface of infinite size
S	Sphere	A sphere is defined by origin and radius (No ellipsoid functions available yet)
B	Box	A box primitive is six sided and defined by origin, size as well as a rotation.
C	Cylinder	An elliptic cylinder primitive .
VP	Convex Polygon	Convex Polygon defined by list of vertices.
CP	Concave Polygon	Concave Polygon defined by list of vertices. Automatic backward compatibility with Convex Polygons.
The Process, What does it do?
d	distance	Calculate distance
n	nearest	Calculate nearest
p	project	Calculates projection
x	Intersection	Calculates intersection
dir	direction	Calculates direction
Return, What kind of data do I get out of it?
Z	Float	Represents that a float is returned
V	Vector	Represents that a vector is returned
O	Origin	Represents the Origin of the ray or line
D	Direction	Direction from the Origin
E	Edge	Edge of a shape, such as an edge on a box, suffix may mark special case return type

Licenses

#1

//Copyright (c) 1970-2003, Wm. Randolph Franklin
//Copyright (c) 2008, Strife Onizuka (porting to LSL)
//
//Permission is hereby granted, free of charge, to any person obtaining a copy
//of this software and associated documentation files (the "Software"), to deal
//in the Software without restriction, including without limitation the rights
//to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
//copies of the Software, and to permit persons to whom the Software is
//furnished to do so, subject to the following conditions:
//
// 1. Redistributions of source code must retain the above copyright notice,
//    this list of conditions and the following disclaimers.
// 2. Redistributions in binary form must reproduce the above copyright
//    notice in the documentation and/or other materials provided with the
//    distribution.
// 3. The name of W. Randolph Franklin may not be used to endorse or promote
//    products derived from this Software without specific prior written
//    permission. 
 
//THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
//IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
//FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
//AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
//LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
//OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
//SOFTWARE.

#2

// Copyright 2001, softSurfer (www.softsurfer.com); 2008, LSL-port by Nexii Malthus
// This code may be freely used and modified for any purpose
// providing that this copyright notice is included with it.
// SoftSurfer makes no warranty for this code, and cannot be held
// liable for any real or imagined damage resulting from its use.
// Users of this code must verify correctness for their application.

@@ Line 20: / Line 20: @@
 Calculates the vector from a point ''''to'''' the closest point on a line
-<lsl>
+<source lang="lsl2">
 vector gLXdV(vector O,vector D,vector A){
      return (O-A)-((O-A)*D)*D;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 57: / Line 57: @@
 |
 Calculates distance of line to point, same as measuring magnitude of Line and Point Vector, but faster on it's own
-<lsl>
+<source lang="lsl2">
 float gLXdZ(vector O,vector D,vector A){
      vector k = ( A - O ) % D;
      return llSqrt( k * k );}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 71: / Line 71: @@
 |-
 | vector D
-| Direction of Line
+| Direction of Line (unit vector)
 |-
 | vector A
@@ Line 91: / Line 91: @@
 {|cellspacing="0" cellpadding="3" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #ffffff; border-collapse: collapse" width="80%"
 !style="color: #000000; background-color: #aaaaff;" height="20px"|
 ==== Line Nearest Point, Nearest Point ====
 |-
 |
 Returns nearest point on line to given point
-<lsl>
+<source lang="lsl2">
 vector gLXnX(vector O,vector D,vector A){
      return gLXdV(O,D,A) + A;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 136: / Line 137: @@
 |
 Shortest vector of two lines
-<lsl>
+<source lang="lsl2">
 vector gLLdV(vector O1,vector D1,vector O2,vector D2){
      vector A = O2 - O1; vector B = D1 % D2;
      return B*( (A*B)/(B*B) );}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 177: / Line 178: @@
 |
 Returns the distance between two lines
-<lsl>
+<source lang="lsl2">
 float gLLdZ(vector O1,vector D1,vector O2,vector D2){
      vector A = D1%D2;float B = llVecMag(A);A = <A.x/B,A.y/B,A.z/B>;
      return (O2-O1) * A;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 219: / Line 220: @@
 Closest point of two lines
-<lsl>
+<source lang="lsl2">
 vector gLLnX(vector O1,vector D1,vector O2,vector D2){
      vector nO1 = < O1*D1, O1*D2, 0>;
@@ Line 231: / Line 232: @@
      return O1 + D1*t;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 268: / Line 269: @@
 |
 Computes intersection point of two lines, if there is any, else <-1,-1,-1> if none.
-<lsl>
+<source lang="lsl2">
 vector gLLxX( vector A, vector B, vector C, vector D ){
      vector b = B-A; vector d = D-C;
@@ Line 276: / Line 277: @@
      float t = (c.x*d.y - c.y*d.x) / dotperp;
      return <A.x + t*b.x, A.y + t*b.y, 0>;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 314: / Line 315: @@
 |
 Two closest points of two lines on each line
-<lsl>
+<source lang="lsl2">
 vector X1;vector X2;
 gLLnnXX(vector O1,vector D1,vector O2,vector D2){
@@ Line 328: / Line 329: @@
      X1 = O1 + D1*t;
      X2 = X1 + nD1%nD2;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 375: / Line 376: @@
 |
 Input two lines, the function will return a list containing two vectors responding to the line nearest between them. As well as two floats corresponding to the scalar value on the two line of where the line has an end located at.
-<lsl>
+<source lang="lsl2">
 list gLLnL( vector v0, vector v1, vector v2, vector v3 ) {
      float Eps = 0.000001; vector vx; vector vy; vector va; vector vb; vector vc;
@@ Line 385: / Line 386: @@
      float num = d0*d1-d2*d3; x = num/den; y = (d0+d1*x)/d3;
      vx = v0+vc*x; vy = v2+vb*y; return [vx,vy,x,y]; }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 432: / Line 433: @@
 |
 Input two line segments, the function will return a list containing two vectors responding to the line segment nearest between them. As well as two floats corresponding to the scalar value on the two line segments of where the line segment has an end located at.
-<lsl>
+<source lang="lsl2">
 list gLSLSnLS( vector v0, vector v1, vector v2, vector v3 ) {
      float Eps = 0.000001; vector vx; vector vy; vector va; vector vb; vector vc;
@@ Line 444: / Line 445: @@
      if(x<0)x=0; else if(x>1)x=1; if(y<0)y=0; else if(y>1)y=1;
      vx = v0+vc*x; vy = v2+vb*y; return [vx,vy,x,y]; }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 451: / Line 452: @@
 |-
 | vector v0
-| Start of Line 1
+| Start of Line Segment 1
 |-
 | vector v1
-| End of Line 1
+| End of Line Segment 1
 |-
 | vector v2
-| Start of Line 2
+| Start of Line Segment 2
 |-
 | vector v3
-| End of Line 2
+| End of Line Segment 2
 |-
 !style="background-color: #d0d0ee" | Output
@@ Line 466: / Line 467: @@
 |-
 | [vx]
-| Nearest point on line 1 to line 2
+| Nearest point on Line Segment 1 to Line Segment 2
 |-
 | [vy]
-| Nearest point on line 2 to line 1
+| Nearest point on Line Segment 2 to Line Segment 1
 |-
 | [x]
-| Scalar value representing location of vx on line 1 (range [v0,v1])
+| Scalar value representing location of vx on Line Segment 1 (range [v0,v1])
 |-
 | [y]
-| Scalar value representing location of vy on line 2 (range [v2,v3])
+| Scalar value representing location of vy on Line Segment 2 (range [v2,v3])
 |}
 <div style="float:left;font-size: 80%;">
@@ Line 486: / Line 487: @@
 {|cellspacing="0" cellpadding="3" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #ffffff; border-collapse: collapse" width="80%"
 !style="color: #000000; background-color: #aaaaff;" height="20px"|
 ==== Line and Line, two nearest points with vector and distance ====
 |-
 |
 Computes two closest points of two lines, vector and distance
-<lsl>
+<source lang="lsl2">
 vector X1;vector X2;vector V1;float Z1;
 gLLnnXXVZ(vector O1,vector D1,vector O2,vector D2){
@@ Line 506: / Line 508: @@
      V1 = nD1%nD2;
      Z1 = llVecMag(V1);}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 562: / Line 564: @@
 |
 Works out where point (X) is relative to the line of the segment (L0, L1).
-<lsl>
+<source lang="lsl2">
 float gLSPdir( vector L0, vector L1, vector X ){
      return (L1.x - L0.x)*(X.y - L0.y) - (X.x - L0.x)*(L1.y - L0.y);
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 599: / Line 601: @@
 |
 Finds distance of a point from a plane
-<lsl>
+<source lang="lsl2">
 float gPXdZ(vector Pn,float Pd,vector A){
      return A * Pn + Pd;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 636: / Line 638: @@
 |
 Finds vector that points from point to nearest on plane
-<lsl>
+<source lang="lsl2">
 vector gPXdV(vector Pn,float Pd,vector A){
      return -(Pn * A + Pd)*Pn;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 673: / Line 675: @@
 |
 Finds closest point on plane given point
-<lsl>
+<source lang="lsl2">
 vector gPXnX(vector Pn,float Pd,vector A){
      return A - (Pn * A + Pd) * Pn;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 710: / Line 712: @@
 |
 Finds distance to intersection of plane along ray
-<lsl>
+<source lang="lsl2">
 float gPRxZ(vector Pn,float Pd,vector O,vector D){
      return -((Pn*O+Pd)/(Pn*D));}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 750: / Line 752: @@
 |
 Finds distance vector along a ray to a plane
-<lsl>
+<source lang="lsl2">
 vector gPRdV(vector Pn,float Pd,vector O,vector D){
      return D * gPRxZ(Pn,Pd,O,D);}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 794: / Line 796: @@
 |
 Finds intersection point along a ray to a plane
-<lsl>
+<source lang="lsl2">
 vector gPRxX(vector Pn,float Pd,vector O,vector D){
      return O + gPRdV(Pn,Pd,O,D);}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 838: / Line 840: @@
 |
 Finds interesection point of a line and a plane
-<lsl>
+<source lang="lsl2">
 vector gPLxX(vector Pn,float Pd,vector O,vector D){
      return O + D*-( (Pn*O-Pd)/(Pn*D) );}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 878: / Line 880: @@
 |
 Finds line of intersection of two planes
-<lsl>
+<source lang="lsl2">
 vector oO;vector oD;
@@ Line 886: / Line 888: @@
      vector Bleh = (-Pd*Pn);
      oO = Bleh - (Qn*Cross)/(Qn*Bleh+Qd)*Cross/llVecMag(Cross);}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 932: / Line 934: @@
 |
 Projects a ray onto a plane
-<lsl>
+<source lang="lsl2">
 vector oO;vector oD;
@@ Line 939: / Line 941: @@
      vector t = llVecNorm( D - (Pn*((D*Pn)/(Pn*Pn))) );t = <1.0/t.x,1.0/t.y,1.0/t.z>;
      oD = Pn%t;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 987: / Line 989: @@
 |
 Finds intersection point of sphere and ray
-<lsl>
+<source lang="lsl2">
 vector gSRxX(vector Sp, float Sr, vector Ro, vector Rd){
      float t; Ro -= Sp;
@@ Line 1,026: / Line 1,028: @@
      return Sp + Ro + (t * Rd);
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,064: / Line 1,066: @@
 |
 Finds if there is a intersection of sphere and ray
-<lsl>
+<source lang="lsl2">
 integer gSRx(vector Sp, float Sr, vector Ro, vector Rd){
      float t;Ro = Ro - Sp;
@@ Line 1,079: / Line 1,081: @@
      return TRUE;
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,118: / Line 1,120: @@
 |
 Finds projected distance of a point along a ray
-<lsl>
+<source lang="lsl2">
 float gRXpZ(vector O,vector D,vector A){
      return (A-O)*D;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,157: / Line 1,159: @@
 |
 Finds intersection of a Ray to a Box and returns intersection distance, otherwise -1 if there is no legal intersection.
-<lsl>
+<source lang="lsl2">
 float gBRxZ(vector Ro,vector Rd, vector Bo, vector Bs, rotation Br){
      vector oB = (Ro-Bo)/Br;    vector dB = Rd/Br;    vector eB = 0.5*Bs;
@@ Line 1,214: / Line 1,216: @@
      return mD;
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,254: / Line 1,256: @@
 |
 Finds intersection of a Ray to a Box and returns intersection point, otherwise ZERO_VECTOR if there is no legal intersection.
-<lsl>
+<source lang="lsl2">
 vector gBRxX( vector Ro, vector Rd, vector Bo, vector Bs, rotation Br){
      float k = gBRxZ(Ro,Rd,Bo,Bs,Br);
      if( k != -1.0 ) return Ro + Rd * k;
      else return ZERO_VECTOR;}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,304: / Line 1,306: @@
 |
 Finds if there is an intersection of a Point and a Box and returns boolean
-<lsl>
+<source lang="lsl2">
 integer gBXx(vector A, vector Bo, vector Bs, rotation Br){
      vector eB = 0.5*Bs; vector rA = (A-Bo)/Br;
      return (rA.x<eB.x && rA.x>-eB.x && rA.y<eB.y && rA.y>-eB.y && rA.z<eB.z && rA.z>-eB.z); }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,346: / Line 1,348: @@
 |
 Processes point on nearest edge of box to given point
-<lsl>
+<source lang="lsl2">
 vector gBXnEX(vector A, vector Bo, vector Bs, rotation Br){
      vector eB = 0.5*<llFabs(Bs.x),llFabs(Bs.y),llFabs(Bs.z)>;
@@ Line 1,394: / Line 1,396: @@
      return Bo + ( X * Br );}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,442: / Line 1,444: @@
 |
 Finds if there is an intersection of a Point and a Cylinder and returns boolean
-<lsl>
+<source lang="lsl2">
 integer gCXx( vector A, vector O, rotation R, vector S ) {
      A = ( A - O ) / R;// Converts to local object frame
@@ Line 1,448: / Line 1,450: @@
          && llFabs(A.z/S.z*2) <= 1.;// Test top/bottom
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,489: / Line 1,491: @@
 |
 Figures out if point is inside of polygon or otherwise.
-<lsl>
+<source lang="lsl2">
 integer gCPXx( list CP, vector X )
 {//Copyright (c) 1970-2003, Wm. Randolph Franklin; 2008, Strife Onizuka
@@ Line 1,508: / Line 1,510: @@
      return c;
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,539: / Line 1,541: @@
 |
 Figures out if line segment intersects with polygon.
-<lsl>
+<source lang="lsl2">
 integer gVPLSx( vector P0, vector P1, list VP ){
      //Copyright 2001, softSurfer (www.softsurfer.com); 2008, Nexii Malthus
@@ Line 1,565: / Line 1,567: @@
      return TRUE;
 }
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,585: / Line 1,587: @@
 !style="background-color: #eed0d0" colspan="2"| Requirement
 |-
-|style="background-color: #eed0d0" | <lsl>float Perp( vector U, vector V ){ return U.x*V.y - U.y*V.x; }</lsl>
+|style="background-color: #eed0d0" | <source lang="lsl2">float Perp( vector U, vector V ){ return U.x*V.y - U.y*V.x; }</source>
 | Perpendicular dot product
 |-
@@ Line 1,606: / Line 1,608: @@
 |
 Projects a vector A by vector B.
-<lsl>
+<source lang="lsl2">
 vector Project3D(vector A,vector B){
      return B * ( ( A * B ) / ( B * B ) );}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,640: / Line 1,642: @@
 |
 Reflects Ray R with surface normal N
-<lsl>
+<source lang="lsl2">
 vector Reflect(vector R,vector N){
      return R - 2 * N * ( R * N );}
-</lsl>
+</source>
 {|cellspacing="0" cellpadding="6" border="1" style="border: 1px solid #aaaaaa; margin: 1em 1em 1em 0pt; background-color: #e0e0ff; border-collapse: collapse"
@@ Line 1,771: / Line 1,773: @@
 ==== #1 ====
-<lsl>
+<source lang="lsl2">
 //Copyright (c) 1970-2003, Wm. Randolph Franklin
 //Copyright (c) 2008, Strife Onizuka (porting to LSL)
@@ Line 1,798: / Line 1,800: @@
 //OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 //SOFTWARE.
-</lsl>
+</source>
 ==== #2 ====
-<lsl>
+<source lang="lsl2">
 // Copyright 2001, softSurfer (www.softsurfer.com); 2008, LSL-port by Nexii Malthus
 // This code may be freely used and modified for any purpose
@@ Line 1,808: / Line 1,810: @@
 // liable for any real or imagined damage resulting from its use.
 // Users of this code must verify correctness for their application.
-</lsl>
+</source>

Difference between revisions of "Geometric"

Latest revision as of 21:00, 24 January 2015

Geometric Library

Line and Point, Vector

Line and Point, Distance

Line Nearest Point, Nearest Point

Line and Line, Vector

Line and Line, Distance

Line and Line, Nearest point

Line and Line, intersection point

Line and Line, two nearest points of lines

Line and Line, nearest line

Line and Line Segments, nearest line segment

Line and Line, two nearest points with vector and distance

Line and Point, Direction

Plane and Point, Distance

Plane and Point, Vector

Plane and Point, Nearest point

Plane and Ray, Intersection Distance

Plane and Ray, Vector

Plane and Ray, Intersection Point

Plane and Line, Intersection Point

Plane and Plane, Intersection Line

Plane and Ray, Projection

Sphere and Ray, Intersection Point

Sphere and Ray, Intersection Boolean

Ray and Point, projected distance

Box and Ray, Intersection Distance

Box and Ray, Intersection Point

Box and Point, Intersection Boolean

Box and Point, Nearest Point on Edge

Cylinder and Point, Intersection Boolean

Polygon and Point, Intersection Boolean

Polygon and Line Segment, Intersection Boolean

3D Projection

Reflection

#1

#2

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