162 lines
3.5 KiB
Go
162 lines
3.5 KiB
Go
package govector
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import (
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"math"
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)
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// A and B represent two opposite corners of axis-aligned boundin box
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type AABB2d struct {
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A Point2d `json:A`
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B Point2d `json:B`
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}
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type Polygon2d struct {
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Points []Vector2d `json:"points"`
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Normals []Vector2d `json:"normals"`
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Origin Point2d `json:"origin"`
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}
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func (p Polygon2d) Edge(i int) (Point2d, Vector2d) {
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p1 := Point2d{}
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p2 := Point2d{}
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if i == len(p.Points)-1 {
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p1 = p.Origin.Add(p.Points[i])
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p2 = p.Origin.Add(p.Points[0])
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} else {
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p1 = p.Origin.Add(p.Points[i])
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p2 = p.Origin.Add(p.Points[i+1])
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}
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return p1, p2.Sub(p1)
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}
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type Vector2d struct {
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X float32 `json:"x"`
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Y float32 `json:"y"`
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}
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type Point2d struct {
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X float32 `json:"x"`
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Y float32 `json:"y"`
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}
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const Epsilon = 1e-7
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const Rad2deg = 180 / math.Pi
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const Deg2rad = math.Pi / 180
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func (p1 Point2d) Sub(p2 Point2d) Vector2d {
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return Vector2d{p1.X - p2.X, p1.Y - p2.Y}
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}
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func (p Point2d) Add(v Vector2d) Point2d {
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return Point2d{p.X + v.X, p.Y + v.Y}
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}
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func (v Vector2d) Mag() float32 {
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return float32(math.Abs(math.Sqrt(float64(v.X*v.X) + float64(v.Y*v.Y))))
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}
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func (v Vector2d) MagSquared() float32 {
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return float32(math.Abs(float64(v.X*v.X) + float64(v.Y*v.Y)))
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}
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func (v Vector2d) PopPop() float32 {
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return v.Mag()
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}
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func (v Vector2d) Scale(s float32) Vector2d {
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return Vector2d{v.X * s, v.Y * s}
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}
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func (v1 Vector2d) Cross(v2 Vector2d) float32 {
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return v1.X*v2.Y - v1.Y*v2.X
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}
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func (v1 Vector2d) Dot(v2 Vector2d) float32 {
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return (v1.X * v2.X) + (v1.Y * v2.Y)
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}
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func (p Point2d) ToVector() Vector2d {
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return Vector2d{p.X, p.Y}
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}
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func (v Vector2d) ToPoint() Point2d {
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return Point2d{v.X, v.Y}
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}
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func (v1 Vector2d) Rotate(a float32) Vector2d {
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x := float64(v1.X)*math.Cos(float64(a)) - float64(v1.Y)*math.Sin(float64(a))
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y := float64(v1.X)*math.Sin(float64(a)) + float64(v1.Y)*math.Cos(float64(a))
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return Vector2d{float32(x), float32(y)}
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}
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func PointInRect(p Point2d, r AABB2d) bool {
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return (p.X > r.A.X) && (p.X < r.B.X) && (p.Y > r.A.Y) && (p.Y < r.B.Y)
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}
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func AASquareAtPoint(p Point2d, edgeLength float32) AABB2d {
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size := edgeLength / 2.0
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return AABB2d{
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A: Point2d{X: p.X - size, Y: p.Y - size},
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B: Point2d{X: p.X + size, Y: p.Y + size}}
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}
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func (r AABB2d) ToPolygon() Polygon2d {
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p := Polygon2d{}
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p.Origin = r.A
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p.Points = append(p.Points, r.A.Sub(p.Origin))
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p.Points = append(p.Points, Point2d{r.A.X, r.B.Y}.Sub(p.Origin))
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p.Points = append(p.Points, r.B.Sub(p.Origin))
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p.Points = append(p.Points, Point2d{r.B.X, r.A.Y}.Sub(p.Origin))
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return p
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}
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func OrientedSquare(center Point2d, heading Vector2d, size float32) Polygon2d {
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out := Polygon2d{}
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out.Origin.X = center.X
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out.Origin.Y = center.Y
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x := heading.Normalize().Scale(size)
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y := Vector2d{-x.Y, x.X}
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z := Point2d{}
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out.Points = append(out.Points, z.Add(x).Add(y).ToVector())
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out.Points = append(out.Points, z.Add(y).Sub(x.ToPoint()))
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out.Points = append(out.Points, z.Sub(x.ToPoint()).ToPoint().Sub(y.ToPoint()))
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out.Points = append(out.Points, z.Add(x).Sub(y.ToPoint()))
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return out
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}
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func (v Vector2d) Normalize() Vector2d {
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if v.X == 0 && v.Y == 0 {
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return v
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}
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m := v.Mag()
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return Vector2d{v.X / m, v.Y / m}
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}
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func Distance(p1, p2 Point2d) float32 {
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return p1.Sub(p2).Mag()
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}
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func Angle(v1, v2 Vector2d) float32 {
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x := (v1.Dot(v2) / (v1.Mag() * v2.Mag()))
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angle := math.Acos(float64(x))
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if math.IsNaN(angle) {
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if math.Abs(float64(v1.X-v2.X)) > Epsilon {
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return 180.0
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} else {
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return 0
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}
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}
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// Determine the sign to see what direction
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// the angle should go in
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if v1.Y*v2.X > v1.X*v2.Y {
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angle = angle * -1.0
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}
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return float32(angle)
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}
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