teknoman117/noise_fs.glsl

## noise_fs.glsl
#version 330 core
#extension GL_EXT_gpu_shader4: enable

#define X_NOISE_GEN      1619
#define Y_NOISE_GEN      31337
#define Z_NOISE_GEN      6971
#define SEED_NOISE_GEN   1013
#define SHIFT_NOISE_GEN  6

#define DEFAULT_PERLIN_FREQUENCY 1.0
#define DEFAULT_PERLIN_LACUNARITY 2.0
#define DEFAULT_PERLIN_OCTAVE_COUNT 8
#define DEFAULT_PERLIN_PERSISTENCE 0.5
#define DEFAULT_PERLIN_SEED 80

// Vector Table
uniform sampler1D vectorTable;

// test
uniform int frame;

// Input color from the vertex stage
in vec2 NoiseOut;

// Output color
out vec4 FinalColor;

/// Performs cubic interpolation between two values bound between two other values.
float CubicInterp (float n0, float n1, float n2, float n3, float a)
{
    float p = (n3 - n2) - (n0 - n1);
    float q = (n0 - n1) - p;
    float r = n2 - n0;
    float s = n1;
    return p * a * a * a + q * a * a + r * a + s;
}

/// Performs linear interpolation between two values.
float LinearInterp (float n0, float n1, float a)
{
    return ((1.0 - a) * n0) + (a * n1);
}

/// Performs linear interpolation between two values.
float LinearInterp2 (float n1, float n0, float a)
{
    return ((1.0 - a) * n0) + (a * n1);
}

/// Maps a value onto a cubic S-curve.
float SCurve3 (float a)
{
    return (a * a * (3.0 - 2.0 * a));
}

/// Maps a value onto a quintic S-curve.
float SCurve5 (float a)
{
    float a3 = a * a * a;
    float a4 = a3 * a;
    float a5 = a4 * a;
    return (6.0 * a5) - (15.0 * a4) + (10.0 * a3);
}

// Int32 range function
float MakeInt32Range (float n)
{
    if (n >= 1073741824.0)
    {
        return (2.0 * mod (n, 1073741824.0)) - 1073741824.0;
    } else if (n <= -1073741824.0)
    {
        return (2.0 * mod (n, 1073741824.0)) + 1073741824.0;
    } else
    {
        return n;
    }
}

float GradientNoise3D (sampler1D vTable, float fx, float fy, float fz, int ix, int iy, int iz, int seed)
{
    // Randomly generate a gradient vector given the integer coordinates of the
    // input value.  This implementation generates a random number and uses it
    // as an index into a normalized-vector lookup table.
    int vectorIndex  = ((X_NOISE_GEN * ix) + (Y_NOISE_GEN * iy) + (Z_NOISE_GEN * iz) + (SEED_NOISE_GEN * seed)) & 0xffffffff;
    vectorIndex     ^= (vectorIndex >> SHIFT_NOISE_GEN);
    vectorIndex     &= 0xff;

    // Fetch the random vector from the vector table
    vec4 vGradient = texelFetch(vTable, vectorIndex, 0);

    // Set up us another vector equal to the distance between the two vectors
    // passed to this function.
    float xvPoint = (fx - float(ix));
    float yvPoint = (fy - float(iy));
    float zvPoint = (fz - float(iz));

    // Now compute the dot product of the gradient vector with the distance
    // vector.  The resulting value is gradient noise.  Apply a scaling value
    // so that this noise value ranges from -1.0 to 1.0.
    return ((vGradient.x * xvPoint) + (vGradient.y * yvPoint) + (vGradient.z * zvPoint)) * 2.12;
}

float GradientCoherentNoise3D (sampler1D vTable, float x, float y, float z, int seed)
{
    // Create a unit-length cube aligned along an integer boundary.  This cube
    // surrounds the input point.
    int x0 = (x > 0.0 ? int(x) : int(x - 1));
    int x1 = x0 + 1;
    int y0 = (y > 0.0? int(y): int(y - 1));
    int y1 = y0 + 1;
    int z0 = (z > 0.0? int(z): int(z - 1));
    int z1 = z0 + 1;

    // Map the difference between the coordinates of the input value and the
    // coordinates of the cube's outer-lower-left vertex onto an S-curve.
    float xs = SCurve3 (x - float(x0));
    float ys = SCurve3 (y - float(y0));
    float zs = SCurve3 (z - float(z0));

    // Now calculate the noise values at each vertex of the cube.  To generate
    // the coherent-noise value at the input point, interpolate these eight
    // noise values using the S-curve value as the interpolant (trilinear
    // interpolation.)
    float n0, n1, ix0, ix1, iy0, iy1;
    n0   = GradientNoise3D (vTable, x, y, z, x0, y0, z0, seed);
    n1   = GradientNoise3D (vTable, x, y, z, x1, y0, z0, seed);
    ix0  = LinearInterp (n0, n1, xs);
    n0   = GradientNoise3D (vTable, x, y, z, x0, y1, z0, seed);
    n1   = GradientNoise3D (vTable, x, y, z, x1, y1, z0, seed);
    ix1  = LinearInterp (n0, n1, xs);
    iy0  = LinearInterp (ix0, ix1, ys);
    n0   = GradientNoise3D (vTable, x, y, z, x0, y0, z1, seed);
    n1   = GradientNoise3D (vTable, x, y, z, x1, y0, z1, seed);
    ix0  = LinearInterp (n0, n1, xs);
    n0   = GradientNoise3D (vTable, x, y, z, x0, y1, z1, seed);
    n1   = GradientNoise3D (vTable, x, y, z, x1, y1, z1, seed);
    ix1  = LinearInterp (n0, n1, xs);
    iy1  = LinearInterp (ix0, ix1, ys);

    return LinearInterp (iy0, iy1, zs);
}

vec3 mod289(vec3 x)
{
    return x - floor(x * (1.0 / 289.0)) * 289.0;
}

vec4 mod289(vec4 x)
{
    return x - floor(x * (1.0 / 289.0)) * 289.0;
}

vec4 permute(vec4 x)
{
    return mod289(((x*34.0)+1.0)*x);
}

vec4 taylorInvSqrt(vec4 r)
{
    return 1.79284291400159 - 0.85373472095314 * r;
}

float snoise(vec3 v)
{
    const vec2  C = vec2(1.0/6.0, 1.0/3.0) ;
    const vec4  D = vec4(0.0, 0.5, 1.0, 2.0);

    // First corner
    vec3 i  = floor(v + dot(v, C.yyy) );
    vec3 x0 =   v - i + dot(i, C.xxx) ;

    // Other corners
    vec3 g = step(x0.yzx, x0.xyz);
    vec3 l = 1.0 - g;
    vec3 i1 = min( g.xyz, l.zxy );
    vec3 i2 = max( g.xyz, l.zxy );

    //   x0 = x0 - 0.0 + 0.0 * C.xxx;
    //   x1 = x0 - i1  + 1.0 * C.xxx;
    //   x2 = x0 - i2  + 2.0 * C.xxx;
    //   x3 = x0 - 1.0 + 3.0 * C.xxx;
    vec3 x1 = x0 - i1 + C.xxx;
    vec3 x2 = x0 - i2 + C.yyy; // 2.0*C.x = 1/3 = C.y
    vec3 x3 = x0 - D.yyy;      // -1.0+3.0*C.x = -0.5 = -D.y

    // Permutations
    i = mod289(i);
    vec4 p = permute( permute( permute(
                                       i.z + vec4(0.0, i1.z, i2.z, 1.0 ))
                              + i.y + vec4(0.0, i1.y, i2.y, 1.0 ))
                     + i.x + vec4(0.0, i1.x, i2.x, 1.0 ));

    // Gradients: 7x7 points over a square, mapped onto an octahedron.
    // The ring size 17*17 = 289 is close to a multiple of 49 (49*6 = 294)
    float n_ = 0.142857142857; // 1.0/7.0
    vec3  ns = n_ * D.wyz - D.xzx;

    vec4 j = p - 49.0 * floor(p * ns.z * ns.z);  //  mod(p,7*7)

    vec4 x_ = floor(j * ns.z);
    vec4 y_ = floor(j - 7.0 * x_ );    // mod(j,N)

    vec4 x = x_ *ns.x + ns.yyyy;
    vec4 y = y_ *ns.x + ns.yyyy;
    vec4 h = 1.0 - abs(x) - abs(y);

    vec4 b0 = vec4( x.xy, y.xy );
    vec4 b1 = vec4( x.zw, y.zw );

    //vec4 s0 = vec4(lessThan(b0,0.0))*2.0 - 1.0;
    //vec4 s1 = vec4(lessThan(b1,0.0))*2.0 - 1.0;
    vec4 s0 = floor(b0)*2.0 + 1.0;
    vec4 s1 = floor(b1)*2.0 + 1.0;
    vec4 sh = -step(h, vec4(0.0));

    vec4 a0 = b0.xzyw + s0.xzyw*sh.xxyy ;
    vec4 a1 = b1.xzyw + s1.xzyw*sh.zzww ;

    vec3 p0 = vec3(a0.xy,h.x);
    vec3 p1 = vec3(a0.zw,h.y);
    vec3 p2 = vec3(a1.xy,h.z);
    vec3 p3 = vec3(a1.zw,h.w);

    //Normalise gradients
    vec4 norm = taylorInvSqrt(vec4(dot(p0,p0), dot(p1,p1), dot(p2, p2), dot(p3,p3)));
    p0 *= norm.x;
    p1 *= norm.y;
    p2 *= norm.z;
    p3 *= norm.w;

    // Mix final noise value
    vec4 m = max(0.6 - vec4(dot(x0,x0), dot(x1,x1), dot(x2,x2), dot(x3,x3)), 0.0);
    m = m * m;
    return 42.0 * dot( m*m, vec4( dot(p0,x0), dot(p1,x1),
                                 dot(p2,x2), dot(p3,x3) ) );
}

float perlin (sampler1D vTable, float x, float y, float z)
{
    float value = 0.0;
    float signal = 0.0;
    float curPersistence = 1.0;
    float nx, ny, nz;
    int seed;

    x *= DEFAULT_PERLIN_FREQUENCY;
    y *= DEFAULT_PERLIN_FREQUENCY;
    z *= DEFAULT_PERLIN_FREQUENCY;

    for (int curOctave = 0; curOctave < DEFAULT_PERLIN_OCTAVE_COUNT; curOctave++)
    {
        // Make sure that these floating-point values have the same range as a 32-
        // bit integer so that we can pass them to the coherent-noise functions.
        nx = MakeInt32Range (x);
        ny = MakeInt32Range (y);
        nz = MakeInt32Range (z);

        // Get the coherent-noise value from the input value and add it to the
        // final result.
        seed = (DEFAULT_PERLIN_SEED + curOctave) & 0xffffffff;
        signal = snoise (vec3(nx, ny, nz + curOctave));
        //signal = GradientCoherentNoise3D (vTable, nx, ny, nz, seed);
        value += signal * curPersistence;

        // Prepare the next octave.
        x *= DEFAULT_PERLIN_LACUNARITY;
        y *= DEFAULT_PERLIN_LACUNARITY;
        z *= DEFAULT_PERLIN_LACUNARITY;
        curPersistence *= DEFAULT_PERLIN_PERSISTENCE;
    }

    return value;
}

// Main shader method
void main (void)
{
    // Get the height at a particular point
    float h = perlin(vectorTable, NoiseOut.x * 2.5, NoiseOut.y * 2.5, (float(frame) / 60.0));
    //float h = GradientCoherentNoise3D(vectorTable, NoiseOut.x * 2.5, NoiseOut.y * 2.5, (float(frame) / 60.0), 0);

    // Apply a gradient to this point
    /*if(h >= -2 && h <= -0.25)
    {
        float a = abs(h + 0.25) / 1.25;
        FinalColor = vec4(0, 0, LinearInterp(1.0, 0.5, a), 1.0);
    }
    else if(h >= -0.25 && h <= 0.0)
    {
        float a = abs(h) / 0.25;
        FinalColor = vec4(0, LinearInterp2(0, 0.5, a), 1.0, 1.0);
    }
    else if(h >= 0 && h <= 0.0625)
    {
        float a = h / 0.0625;
        FinalColor = vec4(LinearInterp2(0.9375, 0, a), LinearInterp2(0.9375, 0.5, a), LinearInterp2(0.25, 1.0, a), 1.0);
    }
    else if(h >= 0.0625 && h <= 0.1250)
    {
        float a = (h - 0.0625) / 0.0625;
        FinalColor = vec4(LinearInterp2(0.125, 0.9375, a), LinearInterp2(0.625, 0.9375, a), LinearInterp2(0, 0.25, a), 1.0);
    }
    else if(h >= 0.1250 && h <= 0.3750)
    {
        float a = (h - 0.1250) / 0.25;
        FinalColor = vec4(LinearInterp2(0.875, 0.125, a), LinearInterp2(0.875, 0.625, a), 0, 1.0);
    }
    else if(h >= 0.3750 && h <= 0.7500)
    {
        float a = (h - 0.3750) / 0.375;
        FinalColor = vec4(LinearInterp2(0.5, 0.875, a), LinearInterp2(0.5, 0.875, a), LinearInterp2(0.5, 0, a), 1.0);
    }
    else if(h >= 0.7500 && h <= 2)
    {
        float a = (h - 0.75) / 0.75;
        FinalColor = vec4(LinearInterp2(1.0, 0.5, a), LinearInterp2(1.0, 0.5, a), LinearInterp2(1.0, 0.5, a), 1.0);
    }*/
    FinalColor = vec4(vec3(1,1,1) * (h/4 + 0.5), 1);
}
	#version 330 core
	#extension GL_EXT_gpu_shader4: enable

	#define X_NOISE_GEN 1619
	#define Y_NOISE_GEN 31337
	#define Z_NOISE_GEN 6971
	#define SEED_NOISE_GEN 1013
	#define SHIFT_NOISE_GEN 6

	#define DEFAULT_PERLIN_FREQUENCY 1.0
	#define DEFAULT_PERLIN_LACUNARITY 2.0
	#define DEFAULT_PERLIN_OCTAVE_COUNT 8
	#define DEFAULT_PERLIN_PERSISTENCE 0.5
	#define DEFAULT_PERLIN_SEED 80

	// Vector Table
	uniform sampler1D vectorTable;

	// test
	uniform int frame;

	// Input color from the vertex stage
	in vec2 NoiseOut;

	// Output color
	out vec4 FinalColor;

	/// Performs cubic interpolation between two values bound between two other values.
	float CubicInterp (float n0, float n1, float n2, float n3, float a)
	{
	float p = (n3 - n2) - (n0 - n1);
	float q = (n0 - n1) - p;
	float r = n2 - n0;
	float s = n1;
	return p * a * a * a + q * a * a + r * a + s;
	}

	/// Performs linear interpolation between two values.
	float LinearInterp (float n0, float n1, float a)
	{
	return ((1.0 - a) * n0) + (a * n1);
	}

	/// Performs linear interpolation between two values.
	float LinearInterp2 (float n1, float n0, float a)
	{
	return ((1.0 - a) * n0) + (a * n1);
	}

	/// Maps a value onto a cubic S-curve.
	float SCurve3 (float a)
	{
	return (a * a * (3.0 - 2.0 * a));
	}

	/// Maps a value onto a quintic S-curve.
	float SCurve5 (float a)
	{
	float a3 = a * a * a;
	float a4 = a3 * a;
	float a5 = a4 * a;
	return (6.0 * a5) - (15.0 * a4) + (10.0 * a3);
	}

	// Int32 range function
	float MakeInt32Range (float n)
	{
	if (n >= 1073741824.0)
	{
	return (2.0 * mod (n, 1073741824.0)) - 1073741824.0;
	} else if (n <= -1073741824.0)
	{
	return (2.0 * mod (n, 1073741824.0)) + 1073741824.0;
	} else
	{
	return n;
	}
	}

	float GradientNoise3D (sampler1D vTable, float fx, float fy, float fz, int ix, int iy, int iz, int seed)
	{
	// Randomly generate a gradient vector given the integer coordinates of the
	// input value. This implementation generates a random number and uses it
	// as an index into a normalized-vector lookup table.
	int vectorIndex = ((X_NOISE_GEN * ix) + (Y_NOISE_GEN * iy) + (Z_NOISE_GEN * iz) + (SEED_NOISE_GEN * seed)) & 0xffffffff;
	vectorIndex ^= (vectorIndex >> SHIFT_NOISE_GEN);
	vectorIndex &= 0xff;

	// Fetch the random vector from the vector table
	vec4 vGradient = texelFetch(vTable, vectorIndex, 0);

	// Set up us another vector equal to the distance between the two vectors
	// passed to this function.
	float xvPoint = (fx - float(ix));
	float yvPoint = (fy - float(iy));
	float zvPoint = (fz - float(iz));

	// Now compute the dot product of the gradient vector with the distance
	// vector. The resulting value is gradient noise. Apply a scaling value
	// so that this noise value ranges from -1.0 to 1.0.
	return ((vGradient.x * xvPoint) + (vGradient.y * yvPoint) + (vGradient.z * zvPoint)) * 2.12;
	}

	float GradientCoherentNoise3D (sampler1D vTable, float x, float y, float z, int seed)
	{
	// Create a unit-length cube aligned along an integer boundary. This cube
	// surrounds the input point.
	int x0 = (x > 0.0 ? int(x) : int(x - 1));
	int x1 = x0 + 1;
	int y0 = (y > 0.0? int(y): int(y - 1));
	int y1 = y0 + 1;
	int z0 = (z > 0.0? int(z): int(z - 1));
	int z1 = z0 + 1;

	// Map the difference between the coordinates of the input value and the
	// coordinates of the cube's outer-lower-left vertex onto an S-curve.
	float xs = SCurve3 (x - float(x0));
	float ys = SCurve3 (y - float(y0));
	float zs = SCurve3 (z - float(z0));

	// Now calculate the noise values at each vertex of the cube. To generate
	// the coherent-noise value at the input point, interpolate these eight
	// noise values using the S-curve value as the interpolant (trilinear
	// interpolation.)
	float n0, n1, ix0, ix1, iy0, iy1;
	n0 = GradientNoise3D (vTable, x, y, z, x0, y0, z0, seed);
	n1 = GradientNoise3D (vTable, x, y, z, x1, y0, z0, seed);
	ix0 = LinearInterp (n0, n1, xs);
	n0 = GradientNoise3D (vTable, x, y, z, x0, y1, z0, seed);
	n1 = GradientNoise3D (vTable, x, y, z, x1, y1, z0, seed);
	ix1 = LinearInterp (n0, n1, xs);
	iy0 = LinearInterp (ix0, ix1, ys);
	n0 = GradientNoise3D (vTable, x, y, z, x0, y0, z1, seed);
	n1 = GradientNoise3D (vTable, x, y, z, x1, y0, z1, seed);
	ix0 = LinearInterp (n0, n1, xs);
	n0 = GradientNoise3D (vTable, x, y, z, x0, y1, z1, seed);
	n1 = GradientNoise3D (vTable, x, y, z, x1, y1, z1, seed);
	ix1 = LinearInterp (n0, n1, xs);
	iy1 = LinearInterp (ix0, ix1, ys);

	return LinearInterp (iy0, iy1, zs);
	}

	vec3 mod289(vec3 x)
	{
	return x - floor(x * (1.0 / 289.0)) * 289.0;
	}

	vec4 mod289(vec4 x)
	{
	return x - floor(x * (1.0 / 289.0)) * 289.0;
	}

	vec4 permute(vec4 x)
	{
	return mod289(((x34.0)+1.0)x);
	}

	vec4 taylorInvSqrt(vec4 r)
	{
	return 1.79284291400159 - 0.85373472095314 * r;
	}

	float snoise(vec3 v)
	{
	const vec2 C = vec2(1.0/6.0, 1.0/3.0) ;
	const vec4 D = vec4(0.0, 0.5, 1.0, 2.0);

	// First corner
	vec3 i = floor(v + dot(v, C.yyy) );
	vec3 x0 = v - i + dot(i, C.xxx) ;

	// Other corners
	vec3 g = step(x0.yzx, x0.xyz);
	vec3 l = 1.0 - g;
	vec3 i1 = min( g.xyz, l.zxy );
	vec3 i2 = max( g.xyz, l.zxy );

	// x0 = x0 - 0.0 + 0.0 * C.xxx;
	// x1 = x0 - i1 + 1.0 * C.xxx;
	// x2 = x0 - i2 + 2.0 * C.xxx;
	// x3 = x0 - 1.0 + 3.0 * C.xxx;
	vec3 x1 = x0 - i1 + C.xxx;
	vec3 x2 = x0 - i2 + C.yyy; // 2.0*C.x = 1/3 = C.y
	vec3 x3 = x0 - D.yyy; // -1.0+3.0*C.x = -0.5 = -D.y

	// Permutations
	i = mod289(i);
	vec4 p = permute( permute( permute(
	i.z + vec4(0.0, i1.z, i2.z, 1.0 ))
	+ i.y + vec4(0.0, i1.y, i2.y, 1.0 ))
	+ i.x + vec4(0.0, i1.x, i2.x, 1.0 ));

	// Gradients: 7x7 points over a square, mapped onto an octahedron.
	// The ring size 1717 = 289 is close to a multiple of 49 (496 = 294)
	float n_ = 0.142857142857; // 1.0/7.0
	vec3 ns = n_ * D.wyz - D.xzx;

	vec4 j = p - 49.0 * floor(p * ns.z * ns.z); // mod(p,7*7)

	vec4 x_ = floor(j * ns.z);
	vec4 y_ = floor(j - 7.0 * x_ ); // mod(j,N)

	vec4 x = x_ *ns.x + ns.yyyy;
	vec4 y = y_ *ns.x + ns.yyyy;
	vec4 h = 1.0 - abs(x) - abs(y);

	vec4 b0 = vec4( x.xy, y.xy );
	vec4 b1 = vec4( x.zw, y.zw );

	//vec4 s0 = vec4(lessThan(b0,0.0))*2.0 - 1.0;
	//vec4 s1 = vec4(lessThan(b1,0.0))*2.0 - 1.0;
	vec4 s0 = floor(b0)*2.0 + 1.0;
	vec4 s1 = floor(b1)*2.0 + 1.0;
	vec4 sh = -step(h, vec4(0.0));

	vec4 a0 = b0.xzyw + s0.xzyw*sh.xxyy ;
	vec4 a1 = b1.xzyw + s1.xzyw*sh.zzww ;

	vec3 p0 = vec3(a0.xy,h.x);
	vec3 p1 = vec3(a0.zw,h.y);
	vec3 p2 = vec3(a1.xy,h.z);
	vec3 p3 = vec3(a1.zw,h.w);

	//Normalise gradients
	vec4 norm = taylorInvSqrt(vec4(dot(p0,p0), dot(p1,p1), dot(p2, p2), dot(p3,p3)));
	p0 *= norm.x;
	p1 *= norm.y;
	p2 *= norm.z;
	p3 *= norm.w;

	// Mix final noise value
	vec4 m = max(0.6 - vec4(dot(x0,x0), dot(x1,x1), dot(x2,x2), dot(x3,x3)), 0.0);
	m = m * m;
	return 42.0 * dot( m*m, vec4( dot(p0,x0), dot(p1,x1),
	dot(p2,x2), dot(p3,x3) ) );
	}

	float perlin (sampler1D vTable, float x, float y, float z)
	{
	float value = 0.0;
	float signal = 0.0;
	float curPersistence = 1.0;
	float nx, ny, nz;
	int seed;

	x *= DEFAULT_PERLIN_FREQUENCY;
	y *= DEFAULT_PERLIN_FREQUENCY;
	z *= DEFAULT_PERLIN_FREQUENCY;

	for (int curOctave = 0; curOctave < DEFAULT_PERLIN_OCTAVE_COUNT; curOctave++)
	{
	// Make sure that these floating-point values have the same range as a 32-
	// bit integer so that we can pass them to the coherent-noise functions.
	nx = MakeInt32Range (x);
	ny = MakeInt32Range (y);
	nz = MakeInt32Range (z);

	// Get the coherent-noise value from the input value and add it to the
	// final result.
	seed = (DEFAULT_PERLIN_SEED + curOctave) & 0xffffffff;
	signal = snoise (vec3(nx, ny, nz + curOctave));
	//signal = GradientCoherentNoise3D (vTable, nx, ny, nz, seed);
	value += signal * curPersistence;

	// Prepare the next octave.
	x *= DEFAULT_PERLIN_LACUNARITY;
	y *= DEFAULT_PERLIN_LACUNARITY;
	z *= DEFAULT_PERLIN_LACUNARITY;
	curPersistence *= DEFAULT_PERLIN_PERSISTENCE;
	}

	return value;
	}

	// Main shader method
	void main (void)
	{
	// Get the height at a particular point
	float h = perlin(vectorTable, NoiseOut.x * 2.5, NoiseOut.y * 2.5, (float(frame) / 60.0));
	//float h = GradientCoherentNoise3D(vectorTable, NoiseOut.x * 2.5, NoiseOut.y * 2.5, (float(frame) / 60.0), 0);

	// Apply a gradient to this point
	/*if(h >= -2 && h <= -0.25)
	{
	float a = abs(h + 0.25) / 1.25;
	FinalColor = vec4(0, 0, LinearInterp(1.0, 0.5, a), 1.0);
	}
	else if(h >= -0.25 && h <= 0.0)
	{
	float a = abs(h) / 0.25;
	FinalColor = vec4(0, LinearInterp2(0, 0.5, a), 1.0, 1.0);
	}
	else if(h >= 0 && h <= 0.0625)
	{
	float a = h / 0.0625;
	FinalColor = vec4(LinearInterp2(0.9375, 0, a), LinearInterp2(0.9375, 0.5, a), LinearInterp2(0.25, 1.0, a), 1.0);
	}
	else if(h >= 0.0625 && h <= 0.1250)
	{
	float a = (h - 0.0625) / 0.0625;
	FinalColor = vec4(LinearInterp2(0.125, 0.9375, a), LinearInterp2(0.625, 0.9375, a), LinearInterp2(0, 0.25, a), 1.0);
	}
	else if(h >= 0.1250 && h <= 0.3750)
	{
	float a = (h - 0.1250) / 0.25;
	FinalColor = vec4(LinearInterp2(0.875, 0.125, a), LinearInterp2(0.875, 0.625, a), 0, 1.0);
	}
	else if(h >= 0.3750 && h <= 0.7500)
	{
	float a = (h - 0.3750) / 0.375;
	FinalColor = vec4(LinearInterp2(0.5, 0.875, a), LinearInterp2(0.5, 0.875, a), LinearInterp2(0.5, 0, a), 1.0);
	}
	else if(h >= 0.7500 && h <= 2)
	{
	float a = (h - 0.75) / 0.75;
	FinalColor = vec4(LinearInterp2(1.0, 0.5, a), LinearInterp2(1.0, 0.5, a), LinearInterp2(1.0, 0.5, a), 1.0);
	}*/
	FinalColor = vec4(vec3(1,1,1) * (h/4 + 0.5), 1);
	}