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SimplexNoise.cpp
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SimplexNoise.cpp
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/**
* @file SimplexNoise.cpp
* @brief A Perlin Simplex Noise C++ Implementation (1D, 2D, 3D).
*
* Copyright (c) 2014-2018 Sebastien Rombauts (sebastien.rombauts@gmail.com)
*
* This C++ implementation is based on the speed-improved Java version 2012-03-09
* by Stefan Gustavson (original Java source code in the public domain).
* http://webstaff.itn.liu.se/~stegu/simplexnoise/SimplexNoise.java:
* - Based on example code by Stefan Gustavson (stegu@itn.liu.se).
* - Optimisations by Peter Eastman (peastman@drizzle.stanford.edu).
* - Better rank ordering method by Stefan Gustavson in 2012.
*
* This implementation is "Simplex Noise" as presented by
* Ken Perlin at a relatively obscure and not often cited course
* session "Real-Time Shading" at Siggraph 2001 (before real
* time shading actually took on), under the title "hardware noise".
* The 3D function is numerically equivalent to his Java reference
* code available in the PDF course notes, although I re-implemented
* it from scratch to get more readable code. The 1D, 2D and 4D cases
* were implemented from scratch by me from Ken Perlin's text.
*
* Distributed under the MIT License (MIT) (See accompanying file LICENSE.txt
* or copy at http://opensource.org/licenses/MIT)
*/
#include "SimplexNoise.h"
#include <cstdint> // int32_t/uint8_t
/**
* Computes the largest integer value not greater than the float one
*
* This method is faster than using (int32_t)std::floor(fp).
*
* I measured it to be approximately twice as fast:
* float: ~18.4ns instead of ~39.6ns on an AMD APU),
* double: ~20.6ns instead of ~36.6ns on an AMD APU),
* Reference: http://www.codeproject.com/Tips/700780/Fast-floor-ceiling-functions
*
* @param[in] fp float input value
*
* @return largest integer value not greater than fp
*/
static inline int32_t fastfloor(float fp) {
int32_t i = static_cast<int32_t>(fp);
return (fp < i) ? (i - 1) : (i);
}
/**
* Permutation table. This is just a random jumble of all numbers 0-255.
*
* This produce a repeatable pattern of 256, but Ken Perlin stated
* that it is not a problem for graphic texture as the noise features disappear
* at a distance far enough to be able to see a repeatable pattern of 256.
*
* This needs to be exactly the same for all instances on all platforms,
* so it's easiest to just keep it as static explicit data.
* This also removes the need for any initialisation of this class.
*
* Note that making this an uint32_t[] instead of a uint8_t[] might make the
* code run faster on platforms with a high penalty for unaligned single
* byte addressing. Intel x86 is generally single-byte-friendly, but
* some other CPUs are faster with 4-aligned reads.
* However, a char[] is smaller, which avoids cache trashing, and that
* is probably the most important aspect on most architectures.
* This array is accessed a *lot* by the noise functions.
* A vector-valued noise over 3D accesses it 96 times, and a
* float-valued 4D noise 64 times. We want this to fit in the cache!
*/
static const uint8_t perm[256] = {
151, 160, 137, 91, 90, 15,
131, 13, 201, 95, 96, 53, 194, 233, 7, 225, 140, 36, 103, 30, 69, 142, 8, 99, 37, 240, 21, 10, 23,
190, 6, 148, 247, 120, 234, 75, 0, 26, 197, 62, 94, 252, 219, 203, 117, 35, 11, 32, 57, 177, 33,
88, 237, 149, 56, 87, 174, 20, 125, 136, 171, 168, 68, 175, 74, 165, 71, 134, 139, 48, 27, 166,
77, 146, 158, 231, 83, 111, 229, 122, 60, 211, 133, 230, 220, 105, 92, 41, 55, 46, 245, 40, 244,
102, 143, 54, 65, 25, 63, 161, 1, 216, 80, 73, 209, 76, 132, 187, 208, 89, 18, 169, 200, 196,
135, 130, 116, 188, 159, 86, 164, 100, 109, 198, 173, 186, 3, 64, 52, 217, 226, 250, 124, 123,
5, 202, 38, 147, 118, 126, 255, 82, 85, 212, 207, 206, 59, 227, 47, 16, 58, 17, 182, 189, 28, 42,
223, 183, 170, 213, 119, 248, 152, 2, 44, 154, 163, 70, 221, 153, 101, 155, 167, 43, 172, 9,
129, 22, 39, 253, 19, 98, 108, 110, 79, 113, 224, 232, 178, 185, 112, 104, 218, 246, 97, 228,
251, 34, 242, 193, 238, 210, 144, 12, 191, 179, 162, 241, 81, 51, 145, 235, 249, 14, 239, 107,
49, 192, 214, 31, 181, 199, 106, 157, 184, 84, 204, 176, 115, 121, 50, 45, 127, 4, 150, 254,
138, 236, 205, 93, 222, 114, 67, 29, 24, 72, 243, 141, 128, 195, 78, 66, 215, 61, 156, 180
};
/**
* Helper function to hash an integer using the above permutation table
*
* This inline function costs around 1ns, and is called N+1 times for a noise of N dimension.
*
* Using a real hash function would be better to improve the "repeatability of 256" of the above permutation table,
* but fast integer Hash functions uses more time and have bad random properties.
*
* @param[in] i Integer value to hash
*
* @return 8-bits hashed value
*/
static inline uint8_t hash(int32_t i) {
return perm[static_cast<uint8_t>(i)];
}
/* NOTE Gradient table to test if lookup-table are more efficient than calculs
static const float gradients1D[16] = {
-8.f, -7.f, -6.f, -5.f, -4.f, -3.f, -2.f, -1.f,
1.f, 2.f, 3.f, 4.f, 5.f, 6.f, 7.f, 8.f
};
*/
/**
* Helper function to compute gradients-dot-residual vectors (1D)
*
* @note that these generate gradients of more than unit length. To make
* a close match with the value range of classic Perlin noise, the final
* noise values need to be rescaled to fit nicely within [-1,1].
* (The simplex noise functions as such also have different scaling.)
* Note also that these noise functions are the most practical and useful
* signed version of Perlin noise.
*
* @param[in] hash hash value
* @param[in] x distance to the corner
*
* @return gradient value
*/
static float grad(int32_t hash, float x) {
const int32_t h = hash & 0x0F; // Convert low 4 bits of hash code
float grad = 1.0f + (h & 7); // Gradient value 1.0, 2.0, ..., 8.0
if ((h & 8) != 0) grad = -grad; // Set a random sign for the gradient
// float grad = gradients1D[h]; // NOTE : Test of Gradient look-up table instead of the above
return (grad * x); // Multiply the gradient with the distance
}
/**
* Helper functions to compute gradients-dot-residual vectors (2D)
*
* @param[in] hash hash value
* @param[in] x x coord of the distance to the corner
* @param[in] y y coord of the distance to the corner
*
* @return gradient value
*/
static float grad(int32_t hash, float x, float y) {
const int32_t h = hash & 0x3F; // Convert low 3 bits of hash code
const float u = h < 4 ? x : y; // into 8 simple gradient directions,
const float v = h < 4 ? y : x;
return ((h & 1) ? -u : u) + ((h & 2) ? -2.0f * v : 2.0f * v); // and compute the dot product with (x,y).
}
/**
* Helper functions to compute gradients-dot-residual vectors (3D)
*
* @param[in] hash hash value
* @param[in] x x coord of the distance to the corner
* @param[in] y y coord of the distance to the corner
* @param[in] z z coord of the distance to the corner
*
* @return gradient value
*/
static float grad(int32_t hash, float x, float y, float z) {
int h = hash & 15; // Convert low 4 bits of hash code into 12 simple
float u = h < 8 ? x : y; // gradient directions, and compute dot product.
float v = h < 4 ? y : h == 12 || h == 14 ? x : z; // Fix repeats at h = 12 to 15
return ((h & 1) ? -u : u) + ((h & 2) ? -v : v);
}
/**
* 1D Perlin simplex noise
*
* Takes around 74ns on an AMD APU.
*
* @param[in] x float coordinate
*
* @return Noise value in the range[-1; 1], value of 0 on all integer coordinates.
*/
float SimplexNoise::noise(float x) {
float n0, n1; // Noise contributions from the two "corners"
// No need to skew the input space in 1D
// Corners coordinates (nearest integer values):
int32_t i0 = fastfloor(x);
int32_t i1 = i0 + 1;
// Distances to corners (between 0 and 1):
float x0 = x - i0;
float x1 = x0 - 1.0f;
// Calculate the contribution from the first corner
float t0 = 1.0f - x0*x0;
// if(t0 < 0.0f) t0 = 0.0f; // not possible
t0 *= t0;
n0 = t0 * t0 * grad(hash(i0), x0);
// Calculate the contribution from the second corner
float t1 = 1.0f - x1*x1;
// if(t1 < 0.0f) t1 = 0.0f; // not possible
t1 *= t1;
n1 = t1 * t1 * grad(hash(i1), x1);
// The maximum value of this noise is 8*(3/4)^4 = 2.53125
// A factor of 0.395 scales to fit exactly within [-1,1]
return 0.395f * (n0 + n1);
}
/**
* 2D Perlin simplex noise
*
* Takes around 150ns on an AMD APU.
*
* @param[in] x float coordinate
* @param[in] y float coordinate
*
* @return Noise value in the range[-1; 1], value of 0 on all integer coordinates.
*/
float SimplexNoise::noise(float x, float y) {
float n0, n1, n2; // Noise contributions from the three corners
// Skewing/Unskewing factors for 2D
static const float F2 = 0.366025403f; // F2 = (sqrt(3) - 1) / 2
static const float G2 = 0.211324865f; // G2 = (3 - sqrt(3)) / 6 = F2 / (1 + 2 * K)
// Skew the input space to determine which simplex cell we're in
const float s = (x + y) * F2; // Hairy factor for 2D
const float xs = x + s;
const float ys = y + s;
const int32_t i = fastfloor(xs);
const int32_t j = fastfloor(ys);
// Unskew the cell origin back to (x,y) space
const float t = static_cast<float>(i + j) * G2;
const float X0 = i - t;
const float Y0 = j - t;
const float x0 = x - X0; // The x,y distances from the cell origin
const float y0 = y - Y0;
// For the 2D case, the simplex shape is an equilateral triangle.
// Determine which simplex we are in.
int32_t i1, j1; // Offsets for second (middle) corner of simplex in (i,j) coords
if (x0 > y0) { // lower triangle, XY order: (0,0)->(1,0)->(1,1)
i1 = 1;
j1 = 0;
} else { // upper triangle, YX order: (0,0)->(0,1)->(1,1)
i1 = 0;
j1 = 1;
}
// A step of (1,0) in (i,j) means a step of (1-c,-c) in (x,y), and
// a step of (0,1) in (i,j) means a step of (-c,1-c) in (x,y), where
// c = (3-sqrt(3))/6
const float x1 = x0 - i1 + G2; // Offsets for middle corner in (x,y) unskewed coords
const float y1 = y0 - j1 + G2;
const float x2 = x0 - 1.0f + 2.0f * G2; // Offsets for last corner in (x,y) unskewed coords
const float y2 = y0 - 1.0f + 2.0f * G2;
// Work out the hashed gradient indices of the three simplex corners
const int gi0 = hash(i + hash(j));
const int gi1 = hash(i + i1 + hash(j + j1));
const int gi2 = hash(i + 1 + hash(j + 1));
// Calculate the contribution from the first corner
float t0 = 0.5f - x0*x0 - y0*y0;
if (t0 < 0.0f) {
n0 = 0.0f;
} else {
t0 *= t0;
n0 = t0 * t0 * grad(gi0, x0, y0);
}
// Calculate the contribution from the second corner
float t1 = 0.5f - x1*x1 - y1*y1;
if (t1 < 0.0f) {
n1 = 0.0f;
} else {
t1 *= t1;
n1 = t1 * t1 * grad(gi1, x1, y1);
}
// Calculate the contribution from the third corner
float t2 = 0.5f - x2*x2 - y2*y2;
if (t2 < 0.0f) {
n2 = 0.0f;
} else {
t2 *= t2;
n2 = t2 * t2 * grad(gi2, x2, y2);
}
// Add contributions from each corner to get the final noise value.
// The result is scaled to return values in the interval [-1,1].
return 45.23065f * (n0 + n1 + n2);
}
/**
* 3D Perlin simplex noise
*
* @param[in] x float coordinate
* @param[in] y float coordinate
* @param[in] z float coordinate
*
* @return Noise value in the range[-1; 1], value of 0 on all integer coordinates.
*/
float SimplexNoise::noise(float x, float y, float z) {
float n0, n1, n2, n3; // Noise contributions from the four corners
// Skewing/Unskewing factors for 3D
static const float F3 = 1.0f / 3.0f;
static const float G3 = 1.0f / 6.0f;
// Skew the input space to determine which simplex cell we're in
float s = (x + y + z) * F3; // Very nice and simple skew factor for 3D
int i = fastfloor(x + s);
int j = fastfloor(y + s);
int k = fastfloor(z + s);
float t = (i + j + k) * G3;
float X0 = i - t; // Unskew the cell origin back to (x,y,z) space
float Y0 = j - t;
float Z0 = k - t;
float x0 = x - X0; // The x,y,z distances from the cell origin
float y0 = y - Y0;
float z0 = z - Z0;
// For the 3D case, the simplex shape is a slightly irregular tetrahedron.
// Determine which simplex we are in.
int i1, j1, k1; // Offsets for second corner of simplex in (i,j,k) coords
int i2, j2, k2; // Offsets for third corner of simplex in (i,j,k) coords
if (x0 >= y0) {
if (y0 >= z0) {
i1 = 1; j1 = 0; k1 = 0; i2 = 1; j2 = 1; k2 = 0; // X Y Z order
} else if (x0 >= z0) {
i1 = 1; j1 = 0; k1 = 0; i2 = 1; j2 = 0; k2 = 1; // X Z Y order
} else {
i1 = 0; j1 = 0; k1 = 1; i2 = 1; j2 = 0; k2 = 1; // Z X Y order
}
} else { // x0<y0
if (y0 < z0) {
i1 = 0; j1 = 0; k1 = 1; i2 = 0; j2 = 1; k2 = 1; // Z Y X order
} else if (x0 < z0) {
i1 = 0; j1 = 1; k1 = 0; i2 = 0; j2 = 1; k2 = 1; // Y Z X order
} else {
i1 = 0; j1 = 1; k1 = 0; i2 = 1; j2 = 1; k2 = 0; // Y X Z order
}
}
// A step of (1,0,0) in (i,j,k) means a step of (1-c,-c,-c) in (x,y,z),
// a step of (0,1,0) in (i,j,k) means a step of (-c,1-c,-c) in (x,y,z), and
// a step of (0,0,1) in (i,j,k) means a step of (-c,-c,1-c) in (x,y,z), where
// c = 1/6.
float x1 = x0 - i1 + G3; // Offsets for second corner in (x,y,z) coords
float y1 = y0 - j1 + G3;
float z1 = z0 - k1 + G3;
float x2 = x0 - i2 + 2.0f * G3; // Offsets for third corner in (x,y,z) coords
float y2 = y0 - j2 + 2.0f * G3;
float z2 = z0 - k2 + 2.0f * G3;
float x3 = x0 - 1.0f + 3.0f * G3; // Offsets for last corner in (x,y,z) coords
float y3 = y0 - 1.0f + 3.0f * G3;
float z3 = z0 - 1.0f + 3.0f * G3;
// Work out the hashed gradient indices of the four simplex corners
int gi0 = hash(i + hash(j + hash(k)));
int gi1 = hash(i + i1 + hash(j + j1 + hash(k + k1)));
int gi2 = hash(i + i2 + hash(j + j2 + hash(k + k2)));
int gi3 = hash(i + 1 + hash(j + 1 + hash(k + 1)));
// Calculate the contribution from the four corners
float t0 = 0.6f - x0*x0 - y0*y0 - z0*z0;
if (t0 < 0) {
n0 = 0.0;
} else {
t0 *= t0;
n0 = t0 * t0 * grad(gi0, x0, y0, z0);
}
float t1 = 0.6f - x1*x1 - y1*y1 - z1*z1;
if (t1 < 0) {
n1 = 0.0;
} else {
t1 *= t1;
n1 = t1 * t1 * grad(gi1, x1, y1, z1);
}
float t2 = 0.6f - x2*x2 - y2*y2 - z2*z2;
if (t2 < 0) {
n2 = 0.0;
} else {
t2 *= t2;
n2 = t2 * t2 * grad(gi2, x2, y2, z2);
}
float t3 = 0.6f - x3*x3 - y3*y3 - z3*z3;
if (t3 < 0) {
n3 = 0.0;
} else {
t3 *= t3;
n3 = t3 * t3 * grad(gi3, x3, y3, z3);
}
// Add contributions from each corner to get the final noise value.
// The result is scaled to stay just inside [-1,1]
return 32.0f*(n0 + n1 + n2 + n3);
}
/**
* Fractal/Fractional Brownian Motion (fBm) summation of 1D Perlin Simplex noise
*
* @param[in] octaves number of fraction of noise to sum
* @param[in] x float coordinate
*
* @return Noise value in the range[-1; 1], value of 0 on all integer coordinates.
*/
float SimplexNoise::fractal(size_t octaves, float x) const {
float output = 0.f;
float denom = 0.f;
float frequency = mFrequency;
float amplitude = mAmplitude;
for (size_t i = 0; i < octaves; i++) {
output += (amplitude * noise(x * frequency));
denom += amplitude;
frequency *= mLacunarity;
amplitude *= mPersistence;
}
return (output / denom);
}
/**
* Fractal/Fractional Brownian Motion (fBm) summation of 2D Perlin Simplex noise
*
* @param[in] octaves number of fraction of noise to sum
* @param[in] x x float coordinate
* @param[in] y y float coordinate
*
* @return Noise value in the range[-1; 1], value of 0 on all integer coordinates.
*/
float SimplexNoise::fractal(size_t octaves, float x, float y) const {
float output = 0.f;
float denom = 0.f;
float frequency = mFrequency;
float amplitude = mAmplitude;
for (size_t i = 0; i < octaves; i++) {
output += (amplitude * noise(x * frequency, y * frequency));
denom += amplitude;
frequency *= mLacunarity;
amplitude *= mPersistence;
}
return (output / denom);
}
/**
* Fractal/Fractional Brownian Motion (fBm) summation of 3D Perlin Simplex noise
*
* @param[in] octaves number of fraction of noise to sum
* @param[in] x x float coordinate
* @param[in] y y float coordinate
* @param[in] z z float coordinate
*
* @return Noise value in the range[-1; 1], value of 0 on all integer coordinates.
*/
float SimplexNoise::fractal(size_t octaves, float x, float y, float z) const {
float output = 0.f;
float denom = 0.f;
float frequency = mFrequency;
float amplitude = mAmplitude;
for (size_t i = 0; i < octaves; i++) {
output += (amplitude * noise(x * frequency, y * frequency, z * frequency));
denom += amplitude;
frequency *= mLacunarity;
amplitude *= mPersistence;
}
return (output / denom);
}