Converting GLSL to Godot shaders
This document explains the differences between Godot's shading language and GLSL and gives practical advice on how to migrate shaders from other sources, such as Shadertoy and The Book of Shaders, into Godot shaders.
For detailed information on Godot's shading language, please refer to the Shading language reference.
GLSL
Godot uses a shading language based on GLSL with the addition of a few quality-of-life features. Accordingly, most features available in GLSL are available in Godot's shading language.
Shader programs
In GLSL, each shader uses a separate program. You have one program for the vertex shader and one for the fragment shader. In Godot, you have a single shader that contains a vertex
and/or a fragment
function. If you only choose to write one, Godot will supply the other.
Godot allows uniform variables and functions to be shared by defining the fragment and vertex shaders in one file. In GLSL, the vertex and fragment programs cannot share variables except when varyings are used.
Vertex attributes
In GLSL, you can pass in per-vertex information using attributes and have the flexibility to pass in as much or as little as you want. In Godot, you have a set number of input attributes, including VERTEX
(position), COLOR
, UV
, UV2
, NORMAL
. Each shaders' page in the shader reference section of the documentation comes with a complete list of its vertex attributes.
gl_Position
gl_Position
receives the final position of a vertex specified in the vertex shader. It is specified by the user in clip space. Typically, in GLSL, the model space vertex position is passed in using a vertex attribute called position
and you handle the conversion from model space to clip space manually.
In Godot, VERTEX
specifies the vertex position in model space at the beginning of the vertex
function. Godot also handles the final conversion to clip space after the user-defined vertex
function is run. If you want to skip the conversion from model to view space, you can set the render_mode
to skip_vertex_transform
. If you want to skip all transforms, set render_mode
to skip_vertex_transform
and set the PROJECTION_MATRIX
to mat4(1.0)
in order to nullify the final transform from view space to clip space.
Varyings
Varyings are a type of variable that can be passed from the vertex shader to the fragment shader. In modern GLSL (3.0 and up), varyings are defined with the in
and out
keywords. A variable going out of the vertex shader is defined with out
in the vertex shader and in
inside the fragment shader.
Main
In GLSL, each shader program looks like a self-contained C-style program. Accordingly, the main entry point is main
. If you are copying a vertex shader, rename main
to vertex
and if you are copying a fragment shader, rename main
to fragment
.
Macros
The Shader preprocessor supports the following macros:
#define
/#undef
#if
,#elif
,#else
,#endif
,defined()
,#ifdef
,#ifndef
#include
(only.gdshaderinc
files and with a maximum depth of 25)#pragma disable_preprocessor
, which disables preprocessing for the rest of the file
Variables
GLSL has many built-in variables that are hard-coded. These variables are not uniforms, so they are not editable from the main program.
Variable | Type | Equivalent | Description |
---|---|---|---|
gl_FragColor | out vec4 | COLOR | Output color for each pixel. |
gl_FragCoord | vec4 | FRAGCOORD | For full screen quads. For smaller quads, use UV. |
gl_Position | vec4 | VERTEX | Position of Vertex, output from Vertex Shader. |
gl_PointSize | float | POINT_SIZE | Size of Point primitive. |
gl_PointCoord | vec2 | POINT_COORD | Position on point when drawing Point primitives. |
gl_FrontFacing | bool | FRONT_FACING | True if front face of primitive. |
Coordinates
gl_FragCoord
in GLSL and FRAGCOORD
in the Godot shading language use the same coordinate system. If using UV in Godot, the y-coordinate will be flipped upside down.
Precision
In GLSL, you can define the precision of a given type (float or int) at the top of the shader with the precision
keyword. In Godot, you can set the precision of individual variables as you need by placing precision qualifiers lowp
, mediump
, and highp
before the type when defining the variable. For more information, see the Shading language reference.
Shadertoy
Shadertoy is a website that makes it easy to write fragment shaders and create pure magic.
Shadertoy does not give the user full control over the shader. It handles all the input and uniforms and only lets the user write the fragment shader.
Types
Shadertoy uses the webgl spec, so it runs a slightly different version of GLSL. However, it still has the regular types, including constants and macros.
mainImage
The main point of entry to a Shadertoy shader is the mainImage
function. mainImage
has two parameters, fragColor
and fragCoord
, which correspond to COLOR
and FRAGCOORD
in Godot, respectively. These parameters are handled automatically in Godot, so you do not need to include them as parameters yourself. Anything in the mainImage
function should be copied into the fragment
function when porting to Godot.
Variables
In order to make writing fragment shaders straightforward and easy, Shadertoy handles passing a lot of helpful information from the main program into the fragment shader for you. A few of these have no equivalents in Godot because Godot has chosen not to make them available by default. This is okay because Godot gives you the ability to make your own uniforms. For variables whose equivalents are listed as "Provide with Uniform", users are responsible for creating that uniform themselves. The description gives the reader a hint about what they can pass in as a substitute.
Variable | Type | Equivalent | Description |
---|---|---|---|
fragColor | out vec4 | COLOR | Output color for each pixel. |
fragCoord | vec2 | FRAGCOORD.xy | For full screen quads. For smaller quads, use UV. |
iResolution | vec3 | 1.0 / SCREEN_PIXEL_SIZE | Can also pass in manually. |
iTime | float | TIME | Time since shader started. |
iTimeDelta | float | Provide with Uniform | Time to render previous frame. |
iFrame | float | Provide with Uniform | Frame number. |
iChannelTime[4] | float | Provide with Uniform | Time since that particular texture started. |
iMouse | vec4 | Provide with Uniform | Mouse position in pixel coordinates. |
iDate | vec4 | Provide with Uniform | Current date, expressed in seconds. |
iChannelResolution[4] | vec3 | 1.0 / TEXTURE_PIXEL_SIZE | Resolution of particular texture. |
iChanneli | Sampler2D | TEXTURE | Godot provides only one built-in; user can make more. |
Coordinates
fragCoord
behaves the same as gl_FragCoord
in Coordinates and FRAGCOORD
in Godot.
The Book of Shaders
Similar to Shadertoy, The Book of Shaders provides access to a fragment shader in the web browser, with which the user may interact. The user is restricted to writing fragment shader code with a set list of uniforms passed in and with no ability to add additional uniforms.
For further help on porting shaders to various frameworks generally, The Book of Shaders provides a page on running shaders in various frameworks.
Types
The Book of Shaders uses the webgl spec, so it runs a slightly different version of GLSL. However, it still has the regular types, including constants and macros.
Main
The entry point for a Book of Shaders fragment shader is main
, just like in GLSL. Everything written in a Book of Shaders main
function should be copied into Godot's fragment
function.
Variables
The Book of Shaders sticks closer to plain GLSL than Shadertoy does. It also implements fewer uniforms than Shadertoy.
Variable | Type | Equivalent | Description |
---|---|---|---|
gl_FragColor | out vec4 | COLOR | Output color for each pixel. |
gl_FragCoord | vec4 | FRAGCOORD | For full screen quads. For smaller quads, use UV. |
u_resolution | vec2 | 1.0 / SCREEN_PIXEL_SIZE | Can also pass in manually. |
u_time | float | TIME | Time since shader started. |
u_mouse | vec2 | Provide with Uniform | Mouse position in pixel coordinates. |
Coordinates
The Book of Shaders uses the same coordinate system as Coordinates.