path: root/StarsEx/Geometry.h

/*  Starshatter: The Open Source Project
    Copyright (c) 2021-2024, Starshatter: The Open Source Project Contributors
    Copyright (c) 2011-2012, Starshatter OpenSource Distribution Contributors
    Copyright (c) 1997-2006, Destroyer Studios LLC.

    AUTHOR:       John DiCamillo


    OVERVIEW
    ========
    Geometric classes: Rect, Vec3, Point, Matrix, Plane
*/

#ifndef Geometry_h
#define Geometry_h

#include "Types.h"

// +--------------------------------------------------------------------+

struct Rect;
struct Insets;
struct Matrix;
struct Vec3;
struct Point;
struct Quaternion;
struct Plane;

#ifndef PI
const double PI = 3.14159265358979323846;
#endif
const double DEGREES = (PI/180);

// +--------------------------------------------------------------------+

struct Rect
{
    static const char* TYPENAME() { return "Rect"; }

    Rect()                                 : x(0),  y(0),  w(0),  h(0)  { }
    Rect(int ix, int iy, int iw, int ih)   : x(ix), y(iy), w(iw), h(ih) { }

    int    operator==(const Rect& r)  const { return x==r.x && y==r.y && w==r.w && h==r.h; }
    int    operator!=(const Rect& r)  const { return x!=r.x || y!=r.y || w!=r.w || h!=r.h; }

    void   Inflate(int dw, int dh);
    void   Deflate(int dw, int dh);
    void   Inset(int left, int right, int top, int bottom);
    int    Contains(int x, int y) const;

    int x, y, w, h;
};

// +--------------------------------------------------------------------+

struct Insets
{
    Insets() : left(0), right(0), top(0), bottom(0) { }
    Insets(WORD l, WORD r, WORD t, WORD b) : left(l), right(r), top(t), bottom(b) { }

    WORD  left;
    WORD  right;
    WORD  top;
    WORD  bottom;
};

// +--------------------------------------------------------------------+

struct Matrix
{
    static const char* TYPENAME() { return "Matrix"; }

    Matrix();
    Matrix(const Matrix& m);
    Matrix(const Point& vrt, const Point& vup, const Point& vpn);

    Matrix& operator =  (const Matrix& m);
    Matrix& operator *= (const Matrix& m);

    double  operator() (int i, int j)   const { return elem[i][j]; }
    double& operator() (int i, int j)         { return elem[i][j]; }

    void Identity();
    void Transpose();
    void Rotate(double roll, double pitch, double yaw);
    void Roll(double roll);
    void Pitch(double pitch);
    void Yaw(double yaw);
    void ComputeEulerAngles(double& roll, double& pitch, double& yaw) const;

    double Cofactor(int i, int j) const;
    void   Invert();

    Matrix Inverse() const {
        Matrix result(*this);
        result.Invert();
        return result;
    }

    Matrix operator*(const Matrix& m) const;
    Point  operator*(const Point & p) const;
    Vec3   operator*(const Vec3&   v) const;

    double elem[3][3];

private:
    Matrix(int no_init) { }
};

// +--------------------------------------------------------------------+

struct Vec2
{
    static const char* TYPENAME() { return "Vec2"; }

    Vec2()                                                      { }
    Vec2(int    ix, int    iy) : x((float) ix), y((float) iy)   { }
    Vec2(float  ix, float  iy) : x(ix),         y(iy)           { }
    Vec2(double ix, double iy) : x((float) ix), y((float) iy)   { }

    operator void*()          const { return (void*) (x || y);    }
    int    operator==(const Vec2& p) const { return x==p.x && y==p.y;    }
    int    operator!=(const Vec2& p) const { return x!=p.x || y!=p.y;    }
    Vec2   operator+ (const Vec2& p) const { return Vec2(x+p.x, y+p.y);  }
    Vec2   operator- (const Vec2& p) const { return Vec2(x-p.x, y-p.y);  }
    Vec2   operator- ()              const { return Vec2(-x, -y);        }
    Vec2   operator* (float s)       const { return Vec2(x*s, y*s);      }
    Vec2   operator/ (float s)       const { return Vec2(x/s, y/s);      }
    float  operator*(const Vec2& p)  const { return (x*p.x + y*p.y);     }

    Vec2&  operator= (const Vec2& p) { x =p.x; y =p.y; return *this;     }
    Vec2&  operator+=(const Vec2& p) { x+=p.x; y+=p.y; return *this;     }
    Vec2&  operator-=(const Vec2& p) { x-=p.x; y-=p.y; return *this;     }
    Vec2&  operator*=(float  s)      { x*=s;   y*=s;   return *this;     }
    Vec2&  operator/=(float  s)      { x/=s;   y/=s;   return *this;     }

    float    length()             const { return (float) sqrt(x*x+y*y);  }
    float    Normalize();
    float    dot(const Vec2& p)   const { return (x*p.x + y*p.y);        }
    Vec2     normal()             const { return Vec2(-y, x);            }

    float x, y;
};

// +--------------------------------------------------------------------+

struct Vec3
{
    static const char* TYPENAME() { return "Vec3"; }

    Vec3() { }
    Vec3(int    ix, int    iy, int    iz) : x((float) ix), y((float) iy), z((float) iz) { }
    Vec3(float  ix, float  iy, float  iz) : x(ix),         y(iy),         z(iz)         { }
    Vec3(double ix, double iy, double iz) : x((float) ix), y((float) iy), z((float) iz) { }

    operator void*()           const { return (void*) (x || y || z);      }
    int    operator==(const Vec3& p)  const { return x==p.x && y==p.y && z==p.z; }
    int    operator!=(const Vec3& p)  const { return x!=p.x || y!=p.y || z!=p.z; }
    Vec3   operator+ (const Vec3& p)  const { return Vec3(x+p.x, y+p.y, z+p.z);  }
    Vec3   operator- (const Vec3& p)  const { return Vec3(x-p.x, y-p.y, z-p.z);  }
    Vec3   operator- ()               const { return Vec3(-x, -y, -z);           }
    Vec3   operator* (float s)        const { return Vec3(x*s, y*s, z*s);        }
    Vec3   operator/ (float s)        const { return Vec3(x/s, y/s, z/s);        }
    float  operator* (const Vec3& p)  const { return (x*p.x + y*p.y + z*p.z);    }
    Vec3   operator* (const Matrix&)  const;

    Vec3&  operator= (const Vec3& p)  { x =p.x; y =p.y; z =p.z; return *this; }
    Vec3&  operator+=(const Vec3& p)  { x+=p.x; y+=p.y; z+=p.z; return *this; }
    Vec3&  operator-=(const Vec3& p)  { x-=p.x; y-=p.y; z-=p.z; return *this; }
    Vec3&  operator*=(float  s)       { x*=s;   y*=s;   z*=s;   return *this; }
    Vec3&  operator/=(float  s)       { x/=s;   y/=s;   z/=s;   return *this; }

    void     SwapYZ() { float t = y; y = z; z = t; }
    float    length() const           { return (float) sqrt(x*x+y*y+z*z); }
    float    Normalize();

    float    dot(const Vec3& p)   const { return (x*p.x + y*p.y + z*p.z);    }
    Vec3     cross(const Vec3& v) const { return Vec3((y*v.z) - (z*v.y),
        (z*v.x) - (x*v.z),
        (x*v.y) - (y*v.x));    }

    float x, y, z;
};

double ClosestApproachTime(const Vec3& loc1, const Vec3& vel1,
const Vec3& loc2, const Vec3& vel2);

// +--------------------------------------------------------------------+

struct Point
{
    static const char* TYPENAME() { return "Point"; }

    Point()                                : x(0),   y(0),   z(0)    { }
    Point(double ix, double iy, double iz) : x(ix),  y(iy),  z(iz)   { }
    Point(const Point& p)                  : x(p.x), y(p.y), z(p.z)  { }
    Point(const Vec3& v)                   : x(v.x), y(v.y), z(v.z)  { }

    operator Vec3() const { return Vec3((float) x, (float) y, (float) z); }

    operator void*()           const { return (void*) (x || y || z);      }
    int   operator==(const Point& p) const { return x==p.x && y==p.y && z==p.z; }
    int   operator!=(const Point& p) const { return x!=p.x || y!=p.y || z!=p.z; }
    Point operator+ (const Point& p) const { return Point(x+p.x, y+p.y, z+p.z); }
    Point operator- (const Point& p) const { return Point(x-p.x, y-p.y, z-p.z); }
    Point operator- ()               const { return Point(-x, -y, -z);          }
    Point operator* (double s)       const { return Point(x*s, y*s, z*s);       }
    Point operator/ (double s)       const { return Point(x/s, y/s, z/s);       }
    double operator*(const Point& p) const { return (x*p.x + y*p.y + z*p.z);    }
    Point operator* (const Matrix& m) const;

    Point& operator= (const Point& p)      { x =p.x; y =p.y; z =p.z; return *this; }
    Point& operator+=(const Point& p)      { x+=p.x; y+=p.y; z+=p.z; return *this; }
    Point& operator-=(const Point& p)      { x-=p.x; y-=p.y; z-=p.z; return *this; }
    Point& operator*=(double s)            { x*=s;   y*=s;   z*=s;   return *this; }
    Point& operator/=(double s)            { x/=s;   y/=s;   z/=s;   return *this; }

    double   length()                const { return sqrt(x*x+y*y+z*z); }
    double   Normalize();
    void     SwapYZ()                      { double t = y; y = z; z = t; }
    Point    OtherHand()             const { return Point(-x, z, y); }

    void     SetElement(int i, double v);

    double   dot(const Point& p)     const { return (x*p.x + y*p.y + z*p.z);    }
    Point    cross(const Point& p)   const { return Point((y*p.z) - (z*p.y),
        (z*p.x) - (x*p.z),
        (x*p.y) - (y*p.x));   }

    double x, y, z;
};

double ClosestApproachTime(const Point& loc1, const Point& vel1,
const Point& loc2, const Point& vel2);

// +--------------------------------------------------------------------+

struct Quaternion
{
    static const char* TYPENAME() { return "Quaternion"; }

    Quaternion()                     : x(0),   y(0),   z(0),   w(0)   { }
    Quaternion(double ix,
    double iy,
    double iz,
    double iw)            : x(ix),  y(iy),  z(iz),  w(iw)  { }
    Quaternion(const Quaternion& q)  : x(q.x), y(q.y), z(q.z), w(q.w) { }

    int   operator==(const Quaternion& q)  const { return x==q.x && y==q.y && z==q.z && w==q.w;  }
    int   operator!=(const Quaternion& q)  const { return x!=q.x || y!=q.y || z!=q.z || w!=q.w;  }

    Quaternion operator+ (const Quaternion& q) const { return Quaternion(x+q.x, y+q.y, z+q.z, w+q.w); }
    Quaternion operator- (const Quaternion& q) const { return Quaternion(x-q.x, y-q.y, z-q.z, w-q.w); }
    Quaternion operator- ()                const { return Quaternion(-x, -y, -z, -w);            }
    Quaternion operator* (double s)        const { return Quaternion(x*s, y*s, z*s, w*s);        }
    Quaternion operator/ (double s)        const { return Quaternion(x/s, y/s, z/s, w/s);        }

    Quaternion& operator= (const Quaternion& q)  { x =q.x; y =q.y; z =q.z; w =q.w; return *this; }
    Quaternion& operator+=(const Quaternion& q)  { x+=q.x; y+=q.y; z+=q.z; w+=q.w; return *this; }
    Quaternion& operator-=(const Quaternion& q)  { x-=q.x; y-=q.y; z-=q.z; w-=q.w; return *this; }
    Quaternion& operator*=(double s)             { x*=s;   y*=s;   z*=s;   w*=s;   return *this; }
    Quaternion& operator/=(double s)             { x/=s;   y/=s;   z/=s;   w/=s;   return *this; }

    double   length()                      const { return sqrt(x*x + y*y + z*z + w*w); }
    double   Normalize();

    double x, y, z, w;
};

// +--------------------------------------------------------------------+

struct Plane
{
    static const char* TYPENAME() { return "Plane"; }

    Plane();
    Plane(const Point& p0,  const Point& p1,  const Point& p2);
    Plane(const Vec3&  v0,  const Vec3&  v1,  const Vec3&  v2);

    void Rotate(const Vec3& v0, const Matrix& m);
    void Translate(const Vec3& v0);

    float          distance;
    Vec3           normal;
};

// +--------------------------------------------------------------------+

double DotProduct(const Point& a, const Point& b);
void   CrossProduct(const Point& a, const Point& b, Point& out);
void   MConcat(double in1[3][3], double in2[3][3], double out[3][3]);

// +--------------------------------------------------------------------+

int lines_intersect(
/* 1st line segment */ double x1, double y1, double x2, double y2,
/* 2nd line segment */ double x3, double y3, double x4, double y4,
/* intersect point  */ double& x, double& y);

// +--------------------------------------------------------------------+

#endif  // Geometry_h