Follow-up of 6194e67e68 - Separated the part that computed triangles normals and lighting inside the fragment shader into a separate shader mm_gouraud, which is only used for the multi-material painting gizmo.

2021-10-15 18:34:31 +02:00 · 2021-10-15 18:34:31 +02:00 · b45675b4e1
commit b45675b4e1
parent 912f73d79c
10 changed files with 179 additions and 84 deletions
--- a/resources/shaders/gouraud.fs
+++ b/resources/shaders/gouraud.fs
@ -50,8 +50,6 @@ varying float world_pos_z;
 varying float world_normal_z;
 varying vec3 eye_normal;

-uniform bool compute_triangle_normals_in_fs;
-
 void main()
 {
    if (any(lessThan(clipping_planes_dots, ZERO)))
@ -59,36 +57,7 @@ void main()
    vec3  color = uniform_color.rgb;
    float alpha = uniform_color.a;

-    vec2  intensity_fs      = intensity;
-    vec3  eye_normal_fs     = eye_normal;
-    float world_normal_z_fs = world_normal_z;
-    if (compute_triangle_normals_in_fs) {
-        vec3 triangle_normal = normalize(cross(dFdx(model_pos.xyz), dFdy(model_pos.xyz)));
-#ifdef FLIP_TRIANGLE_NORMALS
-        triangle_normal = -triangle_normal;
-#endif
-
-        // First transform the normal into camera space and normalize the result.
-        eye_normal_fs = normalize(gl_NormalMatrix * triangle_normal);
-
-        // Compute the cos of the angle between the normal and lights direction. The light is directional so the direction is constant for every vertex.
-        // Since these two are normalized the cosine is the dot product. We also need to clamp the result to the [0,1] range.
-        float NdotL = max(dot(eye_normal_fs, LIGHT_TOP_DIR), 0.0);
-
-        intensity_fs = vec2(0.0, 0.0);
-        intensity_fs.x = INTENSITY_AMBIENT + NdotL * LIGHT_TOP_DIFFUSE;
-        vec3 position = (gl_ModelViewMatrix * model_pos).xyz;
-        intensity_fs.y = LIGHT_TOP_SPECULAR * pow(max(dot(-normalize(position), reflect(-LIGHT_TOP_DIR, eye_normal_fs)), 0.0), LIGHT_TOP_SHININESS);
-
-        // Perform the same lighting calculation for the 2nd light source (no specular applied).
-        NdotL = max(dot(eye_normal_fs, LIGHT_FRONT_DIR), 0.0);
-        intensity_fs.x += NdotL * LIGHT_FRONT_DIFFUSE;
-
-        // z component of normal vector in world coordinate used for slope shading
-        world_normal_z_fs = slope.actived ? (normalize(slope.volume_world_normal_matrix * triangle_normal)).z : 0.0;
-    }
-
-    if (slope.actived && world_normal_z_fs < slope.normal_z - EPSILON) {
+    if (slope.actived && world_normal_z < slope.normal_z - EPSILON) {
        color = vec3(0.7, 0.7, 1.0);
        alpha = 1.0;
    }
@ -96,8 +65,8 @@ void main()
 	color = (any(lessThan(delta_box_min, ZERO)) || any(greaterThan(delta_box_max, ZERO))) ? mix(color, ZERO, 0.3333) : color;
 #ifdef ENABLE_ENVIRONMENT_MAP
    if (use_environment_tex)
-        gl_FragColor = vec4(0.45 * texture2D(environment_tex, normalize(eye_normal_fs).xy * 0.5 + 0.5).xyz + 0.8 * color * intensity_fs.x, alpha);
+        gl_FragColor = vec4(0.45 * texture2D(environment_tex, normalize(eye_normal).xy * 0.5 + 0.5).xyz + 0.8 * color * intensity.x, alpha);
    else
 #endif
-        gl_FragColor = vec4(vec3(intensity_fs.y) + color * intensity_fs.x, alpha);
+        gl_FragColor = vec4(vec3(intensity.y) + color * intensity.x, alpha);
 }
--- a/resources/shaders/gouraud.vs
+++ b/resources/shaders/gouraud.vs
@ -54,26 +54,22 @@ varying float world_pos_z;
 varying float world_normal_z;
 varying vec3 eye_normal;

-uniform bool compute_triangle_normals_in_fs;
-
 void main()
 {
-    if (!compute_triangle_normals_in_fs) {
-        // First transform the normal into camera space and normalize the result.
-        eye_normal = normalize(gl_NormalMatrix * gl_Normal);
+    // First transform the normal into camera space and normalize the result.
+    eye_normal = normalize(gl_NormalMatrix * gl_Normal);

-        // Compute the cos of the angle between the normal and lights direction. The light is directional so the direction is constant for every vertex.
-        // Since these two are normalized the cosine is the dot product. We also need to clamp the result to the [0,1] range.
-        float NdotL = max(dot(eye_normal, LIGHT_TOP_DIR), 0.0);
+    // Compute the cos of the angle between the normal and lights direction. The light is directional so the direction is constant for every vertex.
+    // Since these two are normalized the cosine is the dot product. We also need to clamp the result to the [0,1] range.
+    float NdotL = max(dot(eye_normal, LIGHT_TOP_DIR), 0.0);

-        intensity.x = INTENSITY_AMBIENT + NdotL * LIGHT_TOP_DIFFUSE;
-        vec3 position = (gl_ModelViewMatrix * gl_Vertex).xyz;
-        intensity.y = LIGHT_TOP_SPECULAR * pow(max(dot(-normalize(position), reflect(-LIGHT_TOP_DIR, eye_normal)), 0.0), LIGHT_TOP_SHININESS);
+    intensity.x = INTENSITY_AMBIENT + NdotL * LIGHT_TOP_DIFFUSE;
+    vec3 position = (gl_ModelViewMatrix * gl_Vertex).xyz;
+    intensity.y = LIGHT_TOP_SPECULAR * pow(max(dot(-normalize(position), reflect(-LIGHT_TOP_DIR, eye_normal)), 0.0), LIGHT_TOP_SHININESS);

-        // Perform the same lighting calculation for the 2nd light source (no specular applied).
-        NdotL = max(dot(eye_normal, LIGHT_FRONT_DIR), 0.0);
-        intensity.x += NdotL * LIGHT_FRONT_DIFFUSE;
-    }
+    // Perform the same lighting calculation for the 2nd light source (no specular applied).
+    NdotL = max(dot(eye_normal, LIGHT_FRONT_DIR), 0.0);
+    intensity.x += NdotL * LIGHT_FRONT_DIFFUSE;

    model_pos = gl_Vertex;
    // Point in homogenous coordinates.
@ -90,8 +86,7 @@ void main()
    }

    // z component of normal vector in world coordinate used for slope shading
-    if (!compute_triangle_normals_in_fs)
-        world_normal_z = slope.actived ? (normalize(slope.volume_world_normal_matrix * gl_Normal)).z : 0.0;
+    world_normal_z = slope.actived ? (normalize(slope.volume_world_normal_matrix * gl_Normal)).z : 0.0;

    gl_Position = ftransform();
    // Fill in the scalars for fragment shader clipping. Fragments with any of these components lower than zero are discarded.
--- a/resources/shaders/mm_gouraud.fs
+++ b/resources/shaders/mm_gouraud.fs
@ -0,0 +1,55 @@
+#version 110
+
+#define INTENSITY_CORRECTION 0.6
+
+// normalized values for (-0.6/1.31, 0.6/1.31, 1./1.31)
+const vec3 LIGHT_TOP_DIR = vec3(-0.4574957, 0.4574957, 0.7624929);
+#define LIGHT_TOP_DIFFUSE    (0.8 * INTENSITY_CORRECTION)
+#define LIGHT_TOP_SPECULAR   (0.125 * INTENSITY_CORRECTION)
+#define LIGHT_TOP_SHININESS  20.0
+
+// normalized values for (1./1.43, 0.2/1.43, 1./1.43)
+const vec3 LIGHT_FRONT_DIR = vec3(0.6985074, 0.1397015, 0.6985074);
+#define LIGHT_FRONT_DIFFUSE  (0.3 * INTENSITY_CORRECTION)
+
+#define INTENSITY_AMBIENT    0.3
+
+const vec3  ZERO    = vec3(0.0, 0.0, 0.0);
+const float EPSILON = 0.0001;
+
+uniform vec4 uniform_color;
+
+varying vec3 clipping_planes_dots;
+varying vec4 model_pos;
+
+void main()
+{
+    if (any(lessThan(clipping_planes_dots, ZERO)))
+        discard;
+    vec3  color = uniform_color.rgb;
+    float alpha = uniform_color.a;
+
+    vec3 triangle_normal = normalize(cross(dFdx(model_pos.xyz), dFdy(model_pos.xyz)));
+#ifdef FLIP_TRIANGLE_NORMALS
+    triangle_normal = -triangle_normal;
+#endif
+
+    // First transform the normal into camera space and normalize the result.
+    vec3 eye_normal = normalize(gl_NormalMatrix * triangle_normal);
+
+    // Compute the cos of the angle between the normal and lights direction. The light is directional so the direction is constant for every vertex.
+    // Since these two are normalized the cosine is the dot product. We also need to clamp the result to the [0,1] range.
+    float NdotL = max(dot(eye_normal, LIGHT_TOP_DIR), 0.0);
+
+    // x = diffuse, y = specular;
+    vec2 intensity = vec2(0.0, 0.0);
+    intensity.x = INTENSITY_AMBIENT + NdotL * LIGHT_TOP_DIFFUSE;
+    vec3 position = (gl_ModelViewMatrix * model_pos).xyz;
+    intensity.y = LIGHT_TOP_SPECULAR * pow(max(dot(-normalize(position), reflect(-LIGHT_TOP_DIR, eye_normal)), 0.0), LIGHT_TOP_SHININESS);
+
+    // Perform the same lighting calculation for the 2nd light source (no specular applied).
+    NdotL = max(dot(eye_normal, LIGHT_FRONT_DIR), 0.0);
+    intensity.x += NdotL * LIGHT_FRONT_DIFFUSE;
+
+    gl_FragColor = vec4(vec3(intensity.y) + color * intensity.x, alpha);
+}
--- a/resources/shaders/mm_gouraud.vs
+++ b/resources/shaders/mm_gouraud.vs
@ -0,0 +1,23 @@
+#version 110
+
+const vec3 ZERO = vec3(0.0, 0.0, 0.0);
+
+uniform mat4 volume_world_matrix;
+// Clipping plane, x = min z, y = max z. Used by the FFF and SLA previews to clip with a top / bottom plane.
+uniform vec2 z_range;
+// Clipping plane - general orientation. Used by the SLA gizmo.
+uniform vec4 clipping_plane;
+
+varying vec3 clipping_planes_dots;
+varying vec4 model_pos;
+
+void main()
+{
+    model_pos = gl_Vertex;
+    // Point in homogenous coordinates.
+    vec4 world_pos = volume_world_matrix * gl_Vertex;
+
+    gl_Position = ftransform();
+    // Fill in the scalars for fragment shader clipping. Fragments with any of these components lower than zero are discarded.
+    clipping_planes_dots = vec3(dot(world_pos, clipping_plane), world_pos.z - z_range.x, z_range.y - world_pos.z);
+}