//----------------------------------------------------------------------------- // SolveSpace Outline rendering shader // // Copyright 2016 Aleksey Egorov //----------------------------------------------------------------------------- #version 120 const int EMPHASIZED_AND_CONTOUR = 0; const int EMPHASIZED_WITHOUT_CONTOUR = 1; const int CONTOUR_ONLY = 2; const float feather = 0.5; attribute vec3 pos; attribute vec4 loc; attribute vec3 tan; attribute vec3 nol; attribute vec3 nor; uniform mat4 modelview; uniform mat4 projection; uniform float width; uniform float pixel; uniform int mode; varying vec3 fragLoc; void main() { // get camera direction from modelview matrix vec3 dir = vec3(modelview[0].z, modelview[1].z, modelview[2].z); // perform outline visibility test float ldot = dot(nol, dir); float rdot = dot(nor, dir); bool isOutline = (ldot > -1e-6) == (rdot < 1e-6) || (rdot > -1e-6) == (ldot < 1e-6); bool isTagged = loc.w > 0.5; float visible = float((mode == CONTOUR_ONLY && isOutline) || (mode == EMPHASIZED_AND_CONTOUR && (isOutline || isTagged)) || (mode == EMPHASIZED_WITHOUT_CONTOUR && isTagged && !isOutline)); // calculate line contour extension basis for constant width and caps vec3 norm = normalize(cross(tan, dir)); norm = normalize(norm - dir * dot(dir, norm)); vec3 perp = normalize(cross(dir, norm)); // calculate line extension width considering antialiasing float ext = (width + feather * pixel) * visible; // extend line contour vec3 vertex = pos; vertex += ext * loc.x * normalize(perp); vertex += ext * loc.y * normalize(norm); // write fragment location for calculating caps and antialiasing fragLoc = vec3(loc); // transform resulting vertex with modelview and projection matrices gl_Position = projection * modelview * vec4(vertex, 1.0); }