Sky shaders

Sky shaders are a special type of shader used for drawing sky backgrounds and for updating radiance cubemaps which are used for image-based lighting (IBL). Sky shaders only have one processing function, the sky() function.

There are three places the sky shader is used.

  • First the sky shader is used to draw the sky when you have selected to use a Sky as the background in your scene.

  • Second, the sky shader is used to update the radiance cubemap when using the Sky for ambient color or reflections.

  • Third, the sky shader is used to draw the lower res subpasses which can be used in the high-res background or cubemap pass.

In total, this means the sky shader can run up to six times per frame, however, in practice it will be much less than that because the radiance cubemap does not need to be updated every frame, and not all subpasses will be used. You can change the behavior of the shader based on where it is called by checking the AT_*_PASS booleans. For example:

  1. shader_type sky;
  3. void sky() {
  4.     if (AT_CUBEMAP_PASS) {
  5.         // Sets the radiance cubemap to a nice shade of blue instead of doing
  6.         // expensive sky calculations
  7.         COLOR = vec3(0.2, 0.6, 1.0);
  8.     } else {
  9.         // Do expensive sky calculations for background sky only
  10.         COLOR = get_sky_color(EYEDIR);
  11.     }
  12. }

When using the sky shader to draw a background, the shader will be called for all non-occluded fragments on the screen. However, for the background’s subpasses, the shader will be called for every pixel of the subpass.

When using the sky shader to update the radiance cubemap, the sky shader will be called for every pixel in the cubemap. On the other hand, the shader will only be called when the radiance cubemap needs to be updated. The radiance cubemap needs to be updated when any of the shader parameters are updated. For example, if TIME is used in the shader, then the radiance cubemap will update every frame. The following list of changes force an update of the radiance cubemap:

  • TIME is used.

  • POSITION is used and the camera position changes.

  • If any LIGHTX_* properties are used and any DirectionalLight3D changes.

  • If any uniform is changed in the shader.

  • If the screen is resized and either of the subpasses are used.

Try to avoid updating the radiance cubemap needlessly. If you do need to update the radiance cubemap each frame, make sure your Sky process mode is set to REALTIME.

Note that the process mode only affects the rendering of the radiance cubemap. The visible sky is always rendered by calling the fragment shader for every pixel. With complex fragment shaders, this can result in a high rendering overhead. If the sky is static (the conditions listed above are met) or changes slowly, running the full fragment shader every frame is not needed. This can be avoided by rendering the full sky into the radiance cubemap, and reading from this cubemap when rendering the visible sky. With a completely static sky, this means that it needs to be rendered only once.

The following code renders the full sky into the radiance cubemap and reads from that cubemap for displaying the visible sky:

  1. shader_type sky;
  3. void sky() {
  4.     if (AT_CUBEMAP_PASS) {
  5.         vec3 dir = EYEDIR;
  7.         vec4 col = vec4(0.0);
  9.         // Complex color calculation
  11.         COLOR = col.xyz;
  12.         ALPHA = 1.0;
  13.     } else {
  14.         COLOR = texture(RADIANCE, EYEDIR).rgb;
  15.     }
  16. }

This way, the complex calculations happen only in the cubemap pass, which can be optimized by setting the sky’s process mode and the radiance size to get the desired balance between performance and visual fidelity.

Render modes

Subpasses allow you to do more expensive calculations at a lower resolution to speed up your shaders. For example the following code renders clouds at a lower resolution than the rest of the sky:

  1. shader_type sky;
  2. render_mode use_half_res_pass;
  4. void sky() {
  5.     if (AT_HALF_RES_PASS) {
  6.         // Run cloud calculation for 1/4 of the pixels
  7.         vec4 color = generate_clouds(EYEDIR);
  8.         COLOR = color.rgb;
  9.         ALPHA = color.a;
  10.     } else {
  11.         // At full resolution pass, blend sky and clouds together
  12.         vec3 color = generate_sky(EYEDIR);
  13.         COLOR = color + HALF_RES_COLOR.rgb * HALF_RES_COLOR.a;
  14.     }
  15. }

Render mode

Description

use_half_res_pass

Allows the shader to write to and access the half resolution pass.

use_quarter_res_pass

Allows the shader to write to and access the quarter resolution pass.

disable_fog

If used, fog will not affect the sky.

Built-ins

Values marked as “in” are read-only. Values marked as “out” are for optional writing and will not necessarily contain sensible values. Samplers cannot be written to so they are not marked.

Global built-ins

Global built-ins are available everywhere, including in custom functions.

There are 4 LIGHTX lights, accessed as LIGHT0, LIGHT1, LIGHT2, and LIGHT3.

Built-in

Description

in float TIME

Global time, in seconds.

in vec3 POSITION

Camera position in world space

samplerCube RADIANCE

Radiance cubemap. Can only be read from during background pass. Check !AT_CUBEMAP_PASS before using.

in bool AT_HALF_RES_PASS

Currently rendering to half resolution pass.

in bool AT_QUARTER_RES_PASS

Currently rendering to quarter resolution pass.

in bool AT_CUBEMAP_PASS

Currently rendering to radiance cubemap.

in bool LIGHTX_ENABLED

LightX is visible and in the scene. If false, other light properties may be garbage.

in float LIGHTX_ENERGY

Energy multiplier for LIGHTX.

in vec3 LIGHTX_DIRECTION

Direction that LIGHTX is facing.

in vec3 LIGHTX_COLOR

Color of LIGHTX.

in float LIGHTX_SIZE

Angular diameter of LIGHTX in the sky. Expressed in degrees. For reference, the sun from earth is about 0.5 degrees.

in float PI

A PI constant (3.141592). A ratio of a circle’s circumference to its diameter and amount of radians in half turn.

in float TAU

A TAU constant (6.283185). An equivalent of PI * 2 and amount of radians in full turn.

in float E

A E constant (2.718281). Euler’s number and a base of the natural logarithm.

Sky built-ins

Built-in

Description

in vec3 EYEDIR

Normalized direction of current pixel. Use this as your basic direction for procedural effects.

in vec2 SCREEN_UV

Screen UV coordinate for current pixel. Used to map a texture to the full screen.

in vec2 SKY_COORDS

Sphere UV. Used to map a panorama texture to the sky.

in vec4 HALF_RES_COLOR

Color value of corresponding pixel from half resolution pass. Uses linear filter.

in vec4 QUARTER_RES_COLOR

Color value of corresponding pixel from quarter resolution pass. Uses linear filter.

out vec3 COLOR

Output color.

out float ALPHA

Output alpha value, can only be used in subpasses.

out vec4 FOG

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© Copyright 2014-present Juan Linietsky, Ariel Manzur and the Godot community (CC BY 3.0). Revision 53e837c6.

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