#version 330 core

in vec3 pos;
in vec3 interpolatedNormal;
in vec2 st;

uniform float time;
uniform sampler2D tex;
uniform mat4 rotMat;
uniform vec3 lightPos;
uniform vec3 eyePosition;

//vec3 lightPos = vec3(0.0, 4.0, 2.0);
vec3 LightColor = vec3(0.9,0.9,0.9);
float LightPower = 1.0;


//out vec4 finalcolor;
out vec4 color;


// Authors : Ian McEwan, Ashima Arts and Stefan Gustavson, LiU.
// noise functions
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;
}

// 3-D simplex noise
//
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) ) );
}

// 3-D simplex noise with gradient
// (analytical partial derivatives in x,y,z)
//
float snoise(vec3 v, out vec3 gradient)
{
  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);
  vec4 m2 = m * m;
  vec4 m4 = m2 * m2;
  vec4 pdotx = vec4(dot(p0,x0), dot(p1,x1), dot(p2,x2), dot(p3,x3));

// Determine noise gradient
  vec4 temp = m2 * m * pdotx;
  gradient = -8.0 * (temp.x * x0 + temp.y * x1 + temp.z * x2 + temp.w * x3);
  gradient += m4.x * p0 + m4.y * p1 + m4.z * p2 + m4.w * p3;
  gradient *= 42.0;

  return 42.0 * dot(m4, pdotx);
}

// main
void main () {

	//vec4 light = vec4(1.0, 10.0, 0.0, 0.1);
	vec4 light = vec4(lightPos, 1);
	//light = light*rotMat;
	vec3 colorBlue = vec3(0.0,0.1,0.3);
	vec3 colorLightBlue = vec3(0.0, 0.04, 0.2);
	vec3 colorWhite = vec3(0.9, 0.9, 0.9);

	// Bump map surface
	vec3 grad = vec3(0.0); // To store gradient of noise
	vec3 gradtemp = vec3(0.0); // Temporary gradient for fractal sum
	float bump = 0.2 * snoise(2*pos, grad) + 0.5;
	grad *= 0.4; // Scale gradient with inner derivative
	bump += 0.5 * snoise(pos*4.0, gradtemp);
	grad += 2.0 * gradtemp; // Same influence (double freq, half amp)
	bump += 0.25 * snoise(pos*10.0, gradtemp);
	grad += 4.0 * gradtemp; // Same influence (double freq, half amp)
	
  // Perturb normal
	vec3 perturbation = grad - dot(grad, interpolatedNormal) * interpolatedNormal;
	vec3 norm = interpolatedNormal -  0.2 * perturbation;

  vec3 ballPos = vec3(0.0, 0.0, -0.1);
  ballPos += vec3(0.0, sin(ballPos.z - 2.0*time)/15.0 + cos(ballPos.x + time)/25, 0.0);
  vec3 shadow = vec3(0.0,0.0,0.0);

  // fake shadow
  if( length(pos.xyz-ballPos) < 0.1)
    LightPower = 0.1;

	// Material properties
	vec3 MaterialDiffuseColor = mix(colorBlue, colorLightBlue, 0.5);
	vec3 MaterialAmbientColor = vec3(0.3,0.3,0.3) * MaterialDiffuseColor;
	vec3 MaterialSpecularColor =  vec3(0.9,0.9,0.9);
	
	// Distance to the light
	float distance = length(vec3(light) - pos);

	// Normal of the computed fragment, in camera space
	vec3 n = normalize(norm);

	// Direction of the light (from the fragment to the light)
	vec3 l = normalize(vec3(light)-pos);

	// Cosine of the angle between the normal and the light direction, 
	float cosTheta = clamp( dot( n,l ), 0,1 );

	// Eye vector (towards the camera)
	vec3 E = normalize(eyePosition - pos);
	// Direction in which the triangle reflects the light
	vec3 R = -reflect(l,n);

  // Cosine of the angle between the Eye vector and the Reflect vector,
	float cosAlpha = clamp( dot( E,R ), 0,1 );

	color = vec4(pow(vec3(MaterialAmbientColor
	+ MaterialDiffuseColor * LightColor * LightPower * pow(cosTheta,2) / (distance*0.1)
	+ MaterialSpecularColor * LightColor * LightPower * pow(cosAlpha,100.0) / (distance*0.1) ), vec3(1.0/2.2)), 0.5);
}