base.shader

#shader vertex
#version 410

layout(location = 0) in vec4 position;
layout(location = 1) in vec3 normal;
layout(location = 2) in vec2 uv;
layout(location = 3) in vec4 vertex_color;

out vec2 texCoord;
out vec4 vertex_color_out;
out vec4 pos;

uniform mat4 m2w;

uniform float time = 0;

layout(std140) uniform OK_Matrices{
	mat4 projection;
	mat4 view;
	vec4 view_position;
};



mat4 rotate(float x, float y, float z) {
	return mat4(
		(cos(y + z) + cos(y - z)) / 2, (-sin(y + z) + sin(y - z)) / 2, -sin(y), 0,
		(cos(x + y + z) - cos(x - y + z) + cos(x + y - z) - cos(x - y - z) + 2 * sin(x + z) - 2 * sin(x - z)) / 4, (2 * cos(x + z) + 2 * cos(x - z) - sin(x + y + z) + sin(x - y + z) + sin(x + y - z) - sin(x - y - z)) / 4, (-sin(x + y) - sin(x - y)) / 2, 0,
		(-2 * cos(x + z) + 2 * cos(x - z) + sin(x + y + z) - sin(x - y + z) + sin(x + y - z) - sin(x - y - z)) / 4, (cos(x + y + z) - cos(x - y + z) - cos(x + y - z) + cos(x - y - z) + 2 * sin(x + z) + 2 * sin(x - z)) / 4, (cos(x + y) + cos(x - y)) / 2, 0,
		0, 0, 0, 1
	);
}

out vec3 fragVert;
out vec3 fragNormal;

vec4 MVP(in vec4 position) {
	return projection * view * m2w * position;
}


void main() {

	float F = sqrt(position.x*position.x + position.y*position.y + position.z*position.z) * 0.01;
	mat4 rot = rotate(0, time*F, 0);

	vec4 rotatedNormal = rot * vec4(normal, 1);

	// Pass some variables to the fragment shader
	//fragNormal = vec3(rotatedNormal);
	vertex_color_out = rotatedNormal;
	texCoord = uv;
	fragNormal = mat3(transpose(inverse(m2w))) * normal;

	vec4 out_position = MVP(position);
	gl_Position = out_position;

	fragVert = vec3(m2w * position);
}

#shader fragment
#version 140

#define MAX_LIGHTS 8

in vec4 gl_FragCoord;
in vec2 texCoord;
in vec3 fragNormal;
in vec3 fragVert;

out vec4 out_color;

uniform float time = 0;

uniform sampler2D mainTex;
uniform sampler2D bumpTex;
uniform sampler2D specTex;

uniform float opacity = 0;
uniform float specularity = 1;
uniform float intensity = 1;
uniform float bumpiness = 1;

uniform mat4 m2w;

layout(std140) uniform OK_Matrices{
	mat4 projection;
	mat4 view;
	vec4 view_position;
};

layout(std140) uniform OK_Lights{
	vec4 position;
	vec4 intensities;
	//float spread;
	//float constant;
	//float linear;
	//float quadratic;
} light[MAX_LIGHTS];

vec3 OK_Light(in vec3 position, in vec3 intensities/*, in float constant, in float linear, in float quadratic*/) {
	//Ambience
	float ambientStrength = 0.1;
	vec3 ambient = ambientStrength * intensities;

	// Diffussion
	vec3 norm = normalize(fragNormal);
	vec3 lightDir = normalize(position - fragVert);
	float diffusion = max(dot(norm, lightDir), 0.0);
	vec3 diffuse = diffusion * intensities;
	
	// Specularity
	//float specularStrength = 0.5;
	//vec3 viewDir = normalize(view_position.xyz - fragVert);
	//vec3 reflectDir = reflect(-lightDir, norm);
	//float specPower = pow(max(dot(viewDir, reflectDir), 0.0), 32);
	//vec3 specular = specularStrength * specPower *  intensities;
	
	// Attenuation
	//float distance = length(position - fragVert);
	float attenuation = 1.0; // /(constant + linear * distance + quadratic * (distance * distance));

	return (/*ambient*attenuation +*/ diffuse*intensity*attenuation /*+ specular*specularity*attenuation*/);
}

void main() {

	vec3 diff = texture(mainTex, texCoord).rgb;
	vec3 bump = texture(bumpTex, texCoord).rgb;
	vec3 spec = texture(specTex, texCoord).rgb;

	vec3 light0 = OK_Light(light[0].position.xyz, light[0].intensities.rgb /*,light[0].constant,light[0].linear, light[0].quadratic*/);
	vec3 light1 = OK_Light(light[1].position.xyz, light[1].intensities.rgb /*,light[1].constant,light[1].linear, light[1].quadratic*/);

	//out_color = vec4(fragNormal, 1)*0.2 + 0.8*vec4(texture(mainTex, texCoord).rgb , vertex_color_out.a);
	out_color = vec4( light1, 1);
}
//out_color = vec4(texture(mainTexture, texCoord).rgb * vertex_color_out.rgb, vertex_color_out.a);