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140
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mm_gouraud.fs

mm_gouraud.fs 2.2 KB
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  1. #version 140
    2. 

  2. 

  3. #define INTENSITY_CORRECTION 0.6
    4. 

  4. 

  5. // normalized values for (-0.6/1.31, 0.6/1.31, 1./1.31)
    6. 

  6. const vec3 LIGHT_TOP_DIR = vec3(-0.4574957, 0.4574957, 0.7624929);
    7. 

  7. #define LIGHT_TOP_DIFFUSE    (0.8 * INTENSITY_CORRECTION)
    8. 

  8. #define LIGHT_TOP_SPECULAR   (0.125 * INTENSITY_CORRECTION)
    9. 

  9. #define LIGHT_TOP_SHININESS  20.0
    10. 

  10. 

  11. // normalized values for (1./1.43, 0.2/1.43, 1./1.43)
    12. 

  12. const vec3 LIGHT_FRONT_DIR = vec3(0.6985074, 0.1397015, 0.6985074);
    13. 

  13. #define LIGHT_FRONT_DIFFUSE  (0.3 * INTENSITY_CORRECTION)
    14. 

  14. 

  15. #define INTENSITY_AMBIENT    0.3
    16. 

  16. 

  17. const vec3  ZERO    = vec3(0.0, 0.0, 0.0);
    18. 

  18. const float EPSILON = 0.0001;
    19. 

  19. 

  20. uniform vec4 uniform_color;
    21. 

  21. 

  22. uniform bool volume_mirrored;
    23. 

  23. 

  24. uniform mat4 view_model_matrix;
    25. 

  25. uniform mat3 view_normal_matrix;
    26. 

  26. 

  27. in vec3 clipping_planes_dots;
    28. 

  28. in vec4 model_pos;
    29. 

  29. 

  30. out vec4 out_color;
    31. 

  31. 

  32. void main()
    33. 

  33. {
    34. 

  34.     if (any(lessThan(clipping_planes_dots, ZERO)))
    35. 

  35.         discard;
    36. 

  36.     vec3  color = uniform_color.rgb;
    37. 

  37.     float alpha = uniform_color.a;
    38. 

  38. 

  39.     vec3 triangle_normal = normalize(cross(dFdx(model_pos.xyz), dFdy(model_pos.xyz)));
    40. 

  40. #ifdef FLIP_TRIANGLE_NORMALS
    41. 

  41.     triangle_normal = -triangle_normal;
    42. 

  42. #endif
    43. 

  43. 

  44.     if (volume_mirrored)
    45. 

  45.         triangle_normal = -triangle_normal;
    46. 

  46. 

  47.     // First transform the normal into camera space and normalize the result.
    48. 

  48.     vec3 eye_normal = normalize(view_normal_matrix * triangle_normal);
    49. 

  49. 

  50.     // Compute the cos of the angle between the normal and lights direction. The light is directional so the direction is constant for every vertex.
    51. 

  51.     // Since these two are normalized the cosine is the dot product. We also need to clamp the result to the [0,1] range.
    52. 

  52.     float NdotL = max(dot(eye_normal, LIGHT_TOP_DIR), 0.0);
    53. 

  53. 

  54.     // x = diffuse, y = specular;
    55. 

  55.     vec2 intensity = vec2(0.0);
    56. 

  56.     intensity.x = INTENSITY_AMBIENT + NdotL * LIGHT_TOP_DIFFUSE;
    57. 

  57.     vec3 position = (view_model_matrix * model_pos).xyz;
    58. 

  58.     intensity.y = LIGHT_TOP_SPECULAR * pow(max(dot(-normalize(position), reflect(-LIGHT_TOP_DIR, eye_normal)), 0.0), LIGHT_TOP_SHININESS);
    59. 

  59. 

  60.     // Perform the same lighting calculation for the 2nd light source (no specular applied).
    61. 

  61.     NdotL = max(dot(eye_normal, LIGHT_FRONT_DIR), 0.0);
    62. 

  62.     intensity.x += NdotL * LIGHT_FRONT_DIFFUSE;
    63. 

  63. 

  64.     out_color = vec4(vec3(intensity.y) + color * intensity.x, alpha);
    65. 

  65. }
    66.