Shader Basics
Overview of Shaders
Panda3D uses the GLSL shading language. This section assumes that you have a working knowledge of a shader language. If not, it would be wise to read about GLSL before trying to understand how it fits into Panda3D.
In the past, Panda3D used the Cg shading language. This language is now deprecated. Although Panda3D still supports it in a limited form for compatibility reasons, it is strongly recommended to write new shaders in GLSL instead. Note that support for GLSL is not just limited to the OpenGL graphics back-end; Panda3D is able to automatically transpile the shader to a different shading language, if required by the graphics API.
There are various types of shaders, each capable of describing a different stage in the rendering process. In the most simple case, a model simply has a vertex shader, which describes how each vertex is processed, and a fragment shader (also called a pixel shader in DirectX parlance), describing how the color of each visible pixel on the model is determined. A shader pipeline can be composed of one or more of the following types of shaders:
- Vertex shader
The first stage of the pipeline. It is run for each vertex on the model geometry, and is responsible for preparing the vertex data, usually by transforming the original vertex position to on-screen X, Y coordinates.
- Tessellation control (hull) shader
Optional. When tessellation is used, this specifies how to subdivide the tessellation patch. GLSL only.
- Tessellation evaluation (domain) shader
Optional. When tessellation is used, this determines the position of the tessellated vertices. GLSL only.
- Geometry shader
Optional. This is run for each input primitive (usually a triangle), and determines how the geometry is formed from the input vertices. It may also create additional geometry.
- Fragment (pixel) shaders
This is the last stage of the pipeline before the pixel is blended into the framebuffer, and usually the most useful one. It determines the color of each pixel of the rendered geometry, and therefore performs tasks such as lighting and texturing.
There is also another advanced type of shader called a Compute shader, which stands on its own and does not fit into the pipeline above.
You will usually only find a vertex and fragment shader, since geometry and tessellation shaders are relatively new features that are useful only in more specific cases.
GLSL Shaders
GLSL shaders are always separated up into separate files for vertex, fragment
and geometry shaders, with the main entry point being called main()
.
All GLSL shaders begin with a #version
line indicating the version of the
GLSL standard that the shader is written in. Panda3D fully supports shaders
written in GLSL 330 and above and will automatically convert them as needed to
a different version of GLSL as required by the graphics driver.
GLSL versions older than 330 are supported only for compatibility with older Panda3D projects, and with significant limitations. It is recommended to use only GLSL 330 or higher.
Example Shader
This example applies the first texture of the model using the first texture coordinate set, but switches the red and blue channels around.
This is the vertex shader, named myshader.vert
:
#version 330
// Uniform inputs
uniform mat4 p3d_ModelViewProjectionMatrix;
// Vertex inputs
in vec4 p3d_Vertex;
in vec2 p3d_MultiTexCoord0;
// Output to fragment shader
out vec2 texcoord;
void main() {
gl_Position = p3d_ModelViewProjectionMatrix * p3d_Vertex;
texcoord = p3d_MultiTexCoord0;
}
This is the fragment shader, named myshader.frag
:
#version 330
uniform sampler2D p3d_Texture0;
// Input from vertex shader
in vec2 texcoord;
// Output to the screen
out vec4 p3d_FragColor;
void main() {
vec4 color = texture(p3d_Texture0, texcoord);
p3d_FragColor = color.bgra;
}
Loading a GLSL Shader
To load the above shader and apply it to a model, we can use the following code:
shader = Shader.load(Shader.SL_GLSL,
vertex="myshader.vert",
fragment="myshader.frag")
model.setShader(shader)
To add a geometry shader, simply add the filename of the geometry shader as additional parameter, following the fragment shader.
Cg Shaders
A Cg shader must contain procedures named vshader()
and fshader()
; the
vertex shader and fragment shader respectively. If a geometry shader is used,
then it must also contain a procedure named gshader()
.
Single-File Cg Shaders
To write a Cg shader in a single file, you must create a shader program that looks much like the one shown below. This example preserves position but switches the red and green channels of everything it is applied to:
//Cg
void vshader(float4 vtx_position : POSITION,
float4 vtx_color: COLOR,
out float4 l_position : POSITION,
out float4 l_color0 : COLOR0,
uniform float4x4 mat_modelproj)
{
l_position = mul(mat_modelproj, vtx_position);
l_color0 = vtx_color;
}
void fshader(float4 l_color0 : COLOR0,
out float4 o_color : COLOR)
{
o_color = l_color0.grba;
}
Multi-File Cg Shaders
Cg shaders can be divided into several files as well; one for the vertex shader,
another for the fragment shader, and a third for the geometry shader. The
procedure names are still required to be vshader()
, fshader()
and
gshader()
in their respective shader files.
Loading a Cg Shader
Loading a single-file Cg shader is done with the Shader.load()
procedure. The first parameter is the path to the shader file, and the second is
the shader language, which in this case is Shader.SL_Cg
.
The following is an example of using this procedure:
from panda3d.core import Shader
shader = Shader.load("myshader.sha", Shader.SL_Cg)
model.setShader(shader)
Loading a multi-file Cg shader requires a different set of parameters for the
load()
function; the first being the shader language, and the
second, third and fourth being paths to the vertex, fragment and geometry
shaders respectively. Here is an example:
shader = Shader.load(Shader.SL_Cg,
vertex="myvertexshader.sha",
fragment="myfragmentshader.sha",
geometry="mygeometryshader.sha")
model.setShader(shader)
Applying the Shader
Shaders can be applied to any part of the scene graph. The call to
NodePath.set_shader()
causes the model to be rendered with the shader
passed to it as a parameter. Shaders propagate down the scene graph, like any
other render attribute; the node and everything beneath it will use the shader.
As with other state changes, it is possible to pass a second priority
parameter to indicate that the shader specified at that node should override
shaders specified on a higher or lower node that have a lower priority value.
Fetching Data from the Panda3D Runtime
Each shader program contains a parameter list. Panda3D scans the parameter list
and interprets each parameter name as a request to extract data from the panda
runtime. For example, if the shader contains a parameter declaration
p3d_Vertex
(or for Cg, float3 vtx_position : POSITION
), Panda3D will
interpret that as a request for the vertex position, and it will satisfy the
request. Panda3D will only allow parameter declarations that it recognizes and
understands.
Panda3D will generate an error if the parameter qualifiers do not match what
Panda3D is expecting. For example, if you declare the parameter
float3 vtx_position
, then Panda3D will be happy. If, on the other hand, you
were to declare uniform sampler2D vtx_position
, then Panda3D would generate
two separate errors: Panda3D knows that vtx_position is supposed to be a
float-vector, not a texture, and that it is supposed to be varying, not uniform.
Again, all parameter names must be recognized. There is a list of GLSL shader inputs as well as a list of Cg shader inputs that shows all the valid parameter names and the data that Panda3D will supply.
Supplying Data to the Shader Manually
Most of the data that the shader could want can be fetched from Panda3D at
runtime by using the appropriate parameter names. However, it is sometimes
necessary to supply some user-provided data to the shader. For this, you need
NodePath.set_shader_input()
. Here is an example:
myModel.setShaderInput("tint", (1.0, 0.5, 0.5, 1.0))
The method NodePath.set_shader_input()
stores data that can be accessed
by the shader. It is possible to store data of type Texture
,
NodePath
, and any vector object.
The data that you store using set_shader_input()
isn’t
necessarily used by the shader. Instead, the values are stored in the node, but
unless the shader explicitly asks for them, they will sit unused. So the example
above simply stores the vector, but it is up to the shader whether or not it is
interested in a data item labeled “tint”.
To fetch data that was supplied using set_shader_input()
, the
shader must use the appropriate parameter name.
See the list of GLSL shader inputs or the
list of Cg shader inputs,
many of which refer to the data that was stored using
set_shader_input()
.
Shader inputs propagate down the scene graph, and accumulate as they go. For
example, if you store
set_shader_input("x", 1)
on a node, and
set_shader_input("y", 2)
on its child, then
the child will contain both values.
If you store set_shader_input("z", 1)
on a
node, and set_shader_input("z", 2)
on its
child, then the latter will override the former.
This method also accepts a third parameter, priority, which defaults to zero.
If you store
set_shader_input("w", 1, priority=1000)
on
a node, and
set_shader_input("w", 2, priority=500)
on
the child, then the child will contain a “w” value of 1, because the priority
1000 overrides the priority 500.
To set multiple shader inputs at once, it is most efficient to use a single
call to set_shader_inputs()
:
myModel.setShaderInputs(
tint=(1.0, 0.5, 0.5, 1.0),
tex=myTexture,
)
Shader Render Attributes
The functions NodePath.set_shader()
and
set_shader_input()
are used to apply a shader to a node in
the scene graph. Internally, these functions manipulate a render attribute of
class ShaderAttrib
on the node.
In rare occasions, it is necessary to manipulate ShaderAttrib
objects
explicitly. As an example, the code below shows how to create a
ShaderAttrib
and apply it to a camera:
attrib = ShaderAttrib.make()
attrib = attrib.setShader(Shader.load("myshader.sha"))
attrib = attrib.setShaderInput("tint", (1.0, 0.5, 0.5, 1.0))
base.cam.node().setInitialState(attrib)
Be careful: attribs are immutable objects. So when you apply a function like
set_shader()
or set_shader_input()
to a
ShaderAttrib
, you aren’t modifying the attrib. Instead, these
functions work by returning a new attrib (which contains the modified data).
Deferred Shader Compilation
When you create a Cg shader object, it compiles the shader, checking for syntax errors. But it does not check whether or not your video card is powerful enough to handle the shader. This only happens later on, when you try to render something with the shader. In the case of GLSL shaders, all of this will only happen when the shader is first used to render something.
In the unusual event that your computer contains multiple video cards, the shader may be compiled more than once. It is possible that the compilation could succeed for one video card, and fail for the other.