I would like to draw a large number of quads, each representing a small segment of a curve, so that the curve appears smooth but is really made up of just linear pieces. I also want to be able to set both the thickness of the line and a thickness for a blended part of the line, such that in the blended region the line linearly loses its alpha component. Ideally these lines would be able to be oriented in any way in a 3D scene, though they will most often be in a plane facing the camera.

The problem is that it is that it's hard to blend the line with the background without having the overlapping segments interact with each other, becoming brighter where many overlap. I only want 1 fragment of the line to blend with the background, but it's hard to know which fragment is the correct one if you render each quad separately.

Is there an efficient way to do something like this? Or do I have to do some kind of pre-processing to turn the line into 1 mesh instead of rendering it as a bunch of quads?

[Here is a picture of the problem with the lines intersecting each other & not blending correctly]


Here is a related problem, but it's different because I want to blend the quads so that they fall off linearly. If you implement the solution from this thread, then the blending will look incorrect.

OpenGL blending function to elminate primitive overlap but maintain overall opacity


It looks like you are rendering your lines as simple overlapping rectangles, like this:

lines as simple overlapping rectangles

For perfect results, you need to render an corner cap like this, with nothing overlapping:

rounded corner cap

Think about how you'd construct those orange points. You can approximate the circular cap with a triangle fan. You can also make sharp or flat corners depending on your preference.

In response to @GuyRT's answer: GL_MAX blend mode would look like this:

intersection of feathered lines in MAX blend mode

  • Yes, this works, but if you have dozens of unusual intersections, with segments hitting corners, passing through each other partially, etc. this seems like a huge headache. Is there no way to do this with fragments instead of setting up the lines like this? Further, if you want to do blending, I feel like you already have to do a lot of calculations with fragments anyway, even if you do the no-overlap approach... Mar 18 '14 at 15:28

You could draw your lines into an FBO using glBlendEquation( GL_MAX ), then combine the result with your background using glBlendEquation( GL_FUNC_ADD ) (the default blending equation).

A better option (in light of japreiss's and the OP's comments), would be to draw just the bright part of the lines into an FBO, then blur the result (firstly horizontally into another buffer, then again vertically into the first buffer), before compositing onto the background.

  • GL_MAX looks weird too - see my edited answer for an example image.
    – japreiss
    Mar 18 '14 at 17:07
  • Yes, that doesn't look great. Perhaps just render the bright parts of the line then blur/bloom would work better.
    – GuyRT
    Mar 18 '14 at 17:15
  • Yeah your answer helps, but it looks horrible when you get two intersecting gradients like in that picture (it's nothing wrong with glBlend though, I think it just generally looks bad to draw things like this). This looks great for circles though and other smooth things. I wonder if there is some different way of making the alpha fall off so that you wouldn't get such nasty intersections. Thanks though. Mar 18 '14 at 21:13


fn draw_segments(a: Vec2, b: Vec2, c: Vec2, color: Color, thickness: f32) {
    // goal: draw segment AB and segment BC using triangle primitive.
    let k = vec2(0.5 * thickness, 0.5 * thickness);

    // proj half thickness \\
    let p_ab = (b - a).normalize() * k;
    let p_bc = (c - b).normalize() * k;
    let p_ac = (c - a).normalize() * k;
    // rej half thickness _|_
    let r_ab = p_ab.perp();
    let r_bc = p_bc.perp();
    let r_ac = p_ac.perp();
    // b_s is the shared point south from b used as join
    let b_s = b - r_ac;
    let mid_b_s_from_ab = (b + r_ab - p_ab).lerp(b_s, 0.5);
    let mid_b_s_from_bc = (b + r_bc + p_bc).lerp(b_s, 0.5);

    // main ab quad
    add_triangle(a + r_ab - p_ab, b + r_ab - p_ab, a - r_ab - p_ab, Color::RED);
    add_triangle(b + r_ab - p_ab, a - r_ab - p_ab, b_s, Color::WHITE);
    // corner ab quad
    add_triangle(b + r_ab - p_ab, b + r_ab, mid_b_s_from_ab, Color::GREEN);
    add_triangle(b + r_ab, mid_b_s_from_ab, b, Color::BLUE);
    // corner ab triangle
    add_triangle(mid_b_s_from_ab, b, b_s, Color::RED);
    // corner 'arc'
    add_triangle(b + r_ab, b, b + r_bc, Color::WHITE);
    // corner bc triangle
    add_triangle(mid_b_s_from_bc, b, b_s, Color::WHITE);
    // corner bc quad
    add_triangle(b + r_bc, b + r_bc + p_bc, b, Color::BLUE);
    add_triangle(b + r_bc + p_bc, b, mid_b_s_from_bc, Color::GREEN);
    // main bc quad
    add_triangle(b + r_bc + p_bc, c + r_bc + p_bc, b_s, Color::RED);
    add_triangle(c + r_bc + p_bc, b_s, c - r_bc + p_bc, Color::WHITE);


Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.