package noise import ( "math" "math/rand" ) const perlinB = 0x100 const perlinBM = 0xff const perlinN = 0x1000 // Perlin contains a perlin noise function (both 1D and 2D). type Perlin struct { Seed int64 p [perlinB + perlinB + 2]int g1 [perlinB + perlinB + 2]float64 g2 [perlinB + perlinB + 2][2]float64 } // NewPerlin creates a new perlin noise function with seed seed. func NewPerlin(seed int64) *Perlin { p := &Perlin{Seed: seed} p.Init() return p } func perlinSmoothCurve(t float64) float64 { return t * t * (3. - 2.*t) } func perlinLerp(t, a, b float64) float64 { return a + t*(b-a) } func perlinAt2D(q [2]float64, rx, ry float64) float64 { return rx*q[0] + ry*q[1] } func (p *Perlin) noise1d(x float64) float64 { tx := x + perlinN bx0 := int(tx) & perlinBM bx1 := (bx0 + 1) & perlinBM rx0 := tx - math.Floor(tx) rx1 := rx0 - 1. sx := perlinSmoothCurve(rx0) u := rx0 * p.g1[p.p[bx0]] v := rx1 * p.g1[p.p[bx1]] return perlinLerp(sx, u, v) } func (p *Perlin) noise2d(x, y float64) float64 { tx := x + perlinN bx0 := int(tx) & perlinBM bx1 := (bx0 + 1) & perlinBM rx0 := tx - math.Floor(tx) rx1 := rx0 - 1. ty := y + perlinN by0 := int(ty) & perlinBM by1 := (by0 + 1) & perlinBM ry0 := ty - math.Floor(ty) ry1 := ry0 - 1. i := p.p[bx0] j := p.p[bx1] b00 := p.p[i+by0] b10 := p.p[j+by0] b01 := p.p[i+by1] b11 := p.p[j+by1] sx := perlinSmoothCurve(rx0) sy := perlinSmoothCurve(ry0) u := perlinAt2D(p.g2[b00], rx0, ry0) v := perlinAt2D(p.g2[b10], rx1, ry0) a := perlinLerp(sx, u, v) u = perlinAt2D(p.g2[b01], rx0, ry1) v = perlinAt2D(p.g2[b11], rx1, ry1) b := perlinLerp(sx, u, v) return perlinLerp(sy, a, b) } func normalize2D(v [2]float64) [2]float64 { var s float64 s = math.Sqrt(v[0]*v[0] + v[1]*v[1]) v[0] /= s v[1] /= s return v } // Init initialised the Perlin noise source. Must be called unless struct was created with NewPerlin(...). func (p *Perlin) Init() { r := rand.New(rand.NewSource(p.Seed)) for i := 0; i < perlinB; i++ { p.p[i] = i p.g1[i] = float64((r.Int()%(perlinB+perlinB))-perlinB) / perlinB for j := 0; j < 2; j++ { p.g2[i][j] = float64((r.Int()%(perlinB+perlinB))-perlinB) / perlinB } p.g2[i] = normalize2D(p.g2[i]) for j := 0; j < 3; j++ { r.Int() } } for i := perlinB; i > 0; i-- { j := r.Int() % perlinB p.p[i], p.p[j] = p.p[j], p.p[i] } for i := 0; i < perlinB+2; i++ { p.p[perlinB+i] = p.p[i] p.g1[perlinB+i] = p.g1[i] for j := 0; j < 2; j++ { p.g2[perlinB+i][j] = p.g2[i][j] } } } // Noise1D generates the noise value for x. alpha defines the weight when the sum is formed. Typically it is 2 (function is noisier when alpha approaches 1). beta is the harmonic scaling/spacing (typically 2). n defines the number of harmonics. func (p *Perlin) Noise1D(x, alpha, beta float64, n int) float64 { var val, sum float64 var scale float64 = 1 var coord float64 = x for i := 0; i < n; i++ { val = p.noise1d(coord) sum += val / scale scale *= alpha coord *= beta } return sum } // Noise2D generates the noise value for coordinate (x, y). alpha defines the weight when the sum is formed. Typically it is 2 (function is noisier when alpha approaches 1). beta is the harmonic scaling/spacing (typically 2). n defines the number of harmonics. func (p *Perlin) Noise2D(x, y, alpha, beta float64, n int) float64 { var val, sum float64 var scale float64 = 1 var coord = [2]float64{x, y} for i := 0; i < n; i++ { val = p.noise2d(coord[0], coord[1]) sum += val / scale scale *= alpha coord[0] *= beta coord[1] *= beta } return sum }