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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add here your custom variables
#define MAX_LIGHTS 4
#define LIGHT_DIRECTIONAL 0
#define LIGHT_POINT 1
struct MaterialProperty {
vec3 color;
int useSampler;
sampler2D sampler;
};
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
// Input lighting values
uniform Light lights[MAX_LIGHTS];
uniform vec4 ambient;
uniform vec3 viewPos;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
vec3 lightDot = vec3(0.0);
vec3 normal = normalize(fragNormal);
vec3 viewD = normalize(viewPos - fragPosition);
vec3 specular = vec3(0.0);
// NOTE: Implement here your fragment shader code
for (int i = 0; i < MAX_LIGHTS; i++)
{
if (lights[i].enabled == 1)
{
vec3 light = vec3(0.0);
if (lights[i].type == LIGHT_DIRECTIONAL)
{
light = -normalize(lights[i].target - lights[i].position);
}
if (lights[i].type == LIGHT_POINT)
{
light = normalize(lights[i].position - fragPosition);
}
float NdotL = max(dot(normal, light), 0.0);
lightDot += lights[i].color.rgb*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewD, reflect(-(light), normal))), 16.0); // 16 refers to shine
specular += specCo;
}
}
vec4 finalColor = (texelColor*((colDiffuse + vec4(specular, 1.0))*vec4(lightDot, 1.0)));
finalColor += texelColor*(ambient/10.0);
// Gamma correction
gl_FragColor = pow(finalColor, vec4(1.0/2.2));
}
#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
attribute mat4 instanceTransform;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matNormal;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// NOTE: Add here your custom variables
void main()
{
// Compute MVP for current instance
mat4 mvpi = mvp*instanceTransform;
// Send vertex attributes to fragment shader
fragPosition = vec3(mvpi*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
fragNormal = normalize(vec3(matNormal*vec4(vertexNormal, 1.0)));
// Calculate final vertex position
gl_Position = mvpi*vec4(vertexPosition, 1.0);
}
#version 120
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add here your custom variables
#define MAX_LIGHTS 4
#define LIGHT_DIRECTIONAL 0
#define LIGHT_POINT 1
struct MaterialProperty {
vec3 color;
int useSampler;
sampler2D sampler;
};
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
// Input lighting values
uniform Light lights[MAX_LIGHTS];
uniform vec4 ambient;
uniform vec3 viewPos;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
vec3 lightDot = vec3(0.0);
vec3 normal = normalize(fragNormal);
vec3 viewD = normalize(viewPos - fragPosition);
vec3 specular = vec3(0.0);
// NOTE: Implement here your fragment shader code
for (int i = 0; i < MAX_LIGHTS; i++)
{
if (lights[i].enabled == 1)
{
vec3 light = vec3(0.0);
if (lights[i].type == LIGHT_DIRECTIONAL)
{
light = -normalize(lights[i].target - lights[i].position);
}
if (lights[i].type == LIGHT_POINT)
{
light = normalize(lights[i].position - fragPosition);
}
float NdotL = max(dot(normal, light), 0.0);
lightDot += lights[i].color.rgb*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewD, reflect(-(light), normal))), 16.0); // 16 refers to shine
specular += specCo;
}
}
vec4 finalColor = (texelColor*((colDiffuse + vec4(specular, 1.0))*vec4(lightDot, 1.0)));
finalColor += texelColor*(ambient/10.0);
// Gamma correction
gl_FragColor = pow(finalColor, vec4(1.0/2.2));
}#version 120
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matModel;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// NOTE: Add here your custom variables
// https://github.com/glslify/glsl-inverse
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), (a12*a01 - a02*a11),
b11, (a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), (a11*a00 - a01*a10))/det;
}
// https://github.com/glslify/glsl-transpose
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
// Send vertex attributes to fragment shader
fragPosition = vec3(matModel*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
fragNormal = normalize(normalMatrix*vertexNormal);
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}
#version 330
// Input vertex attributes (from vertex shader)
in vec3 fragPosition;
in vec2 fragTexCoord;
//in vec4 fragColor;
in vec3 fragNormal;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// Output fragment color
out vec4 finalColor;
// NOTE: Add here your custom variables
#define MAX_LIGHTS 4
#define LIGHT_DIRECTIONAL 0
#define LIGHT_POINT 1
struct MaterialProperty {
vec3 color;
int useSampler;
sampler2D sampler;
};
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
// Input lighting values
uniform Light lights[MAX_LIGHTS];
uniform vec4 ambient;
uniform vec3 viewPos;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture(texture0, fragTexCoord);
vec3 lightDot = vec3(0.0);
vec3 normal = normalize(fragNormal);
vec3 viewD = normalize(viewPos - fragPosition);
vec3 specular = vec3(0.0);
// NOTE: Implement here your fragment shader code
for (int i = 0; i < MAX_LIGHTS; i++)
{
if (lights[i].enabled == 1)
{
vec3 light = vec3(0.0);
if (lights[i].type == LIGHT_DIRECTIONAL)
{
light = -normalize(lights[i].target - lights[i].position);
}
if (lights[i].type == LIGHT_POINT)
{
light = normalize(lights[i].position - fragPosition);
}
float NdotL = max(dot(normal, light), 0.0);
lightDot += lights[i].color.rgb*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewD, reflect(-(light), normal))), 16.0); // 16 refers to shine
specular += specCo;
}
}
finalColor = (texelColor*((colDiffuse + vec4(specular, 1.0))*vec4(lightDot, 1.0)));
finalColor += texelColor*(ambient/10.0)*colDiffuse;
// Gamma correction
finalColor = pow(finalColor, vec4(1.0/2.2));
}
#version 330
// Input vertex attributes
in vec3 vertexPosition;
in vec2 vertexTexCoord;
in vec3 vertexNormal;
//in vec4 vertexColor; // Not required
in mat4 instanceTransform;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matNormal;
// Output vertex attributes (to fragment shader)
out vec3 fragPosition;
out vec2 fragTexCoord;
out vec4 fragColor;
out vec3 fragNormal;
// NOTE: Add here your custom variables
void main()
{
// Compute MVP for current instance
mat4 mvpi = mvp*instanceTransform;
// Send vertex attributes to fragment shader
fragPosition = vec3(mvpi*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
//fragColor = vertexColor;
fragNormal = normalize(vec3(matNormal*vec4(vertexNormal, 1.0)));
// Calculate final vertex position
gl_Position = mvpi*vec4(vertexPosition, 1.0);
}
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