Legacy Shader Key Functions and Structures
CCVertInput1
To connect with skeletal animation and data decompression processes, we provide the
CCVertInput
function, which hasgeneral
andstandard
versions, as shown below.// Located in ‘input.chunk’, used to handle vertex input
#define CCVertInput(position) \
CCDecode(position); \
#if CC_USE_MORPH \
applyMorph(position); \
#endif \
#if CC_USE_SKINNING \
CCSkin(position); \
#endif \
#pragma //
// Located in ‘input-standard.chunk’, used to handle standard vertex input
#define CCVertInput(In) \
CCDecode(In); \
#if CC_USE_MORPH \
applyMorph(In); \
#endif \
#if CC_USE_SKINNING \
CCSkin(In); \
#endif \
#pragma //
If you only need to get the positions, you can use the
general
version, and the code for this situation is as follows.#include <legacy/input>
vec4 vert () {
vec3 position;
CCVertInput(position);
// ... TO DO
}
If you also need normals, you can use the
standard
version, as follows.#include <legacy/input-standard>
vec4 vert () {
StandardVertInput In;
CCVertInput(In);
// ... Now the ‘In.position’ is completely initialized, and can be used in the vertext shader
}
In the example code above, the StandardVertInput
object In
returns the positions, normals, and tangents in model space, and completes the skinning calculation for the skeletal animation model.
The definition of the StandardVertInput
structure is as follows.
struct StandardVertInput {
highp vec4 position;
vec3 normal;
vec4 tangent;
};
Note: After including the header files, there is no need to declare these attributes anymore, such as
a_position
,a_normal
,a_tangent
, etc. For other vertex attributes, such as uv, etc., still need to be declared before used.
If you want to connect with the dynamic mesh batching and GPU Instancing features, you need to include the cc-local-batch
and use the CCGetWorldMatrix
function to get the world matrix. Here’s an example.
mat4 matWorld;
CCGetWorldMatrix(matWorld);
mat4 matWorld, matWorldIT;
CCGetWorldMatrixFull(matWorld, matWorldIT);
For more details, please refer to Cocos Shader Built-in Uniforms。
CCFragOutput
Cocos Shader provides a CCFragOutput
function to simplify the output of the fragment shader, which can be used to directly return the values needed by the fragment shader. Here is an example code.
#include <legacy/output>
vec4 frag () {
vec4 o = vec4(0.0);
// ...
return CCFragOutput(o);
}
The CCFragOutput
will decide whether to perform ToneMap
based on the pipeline type. This way, the intermediate color does not need to distinguish whether the current rendering pipeline is an HDR process.
Here is an example code.
vec4 CCFragOutput (vec4 color) {
#if CC_USE_HDR
color.rgb = ACESToneMap(color.rgb);
#endif
color.rgb = LinearToSRGB(color.rgb);
return color;
}
Note:If you use the
CCFragOutput
function to output the final color of fragment shaders, the color must be converted to theLinear
space before performing calculations. This is because theCCFragOutput
assumes that the passed parameters are in theLinear
space and will always call theLinearToSRGB
function to transcode.
If you need to include standard PBR, you can use the StandardSurface
structure together with the CCStandardShadingBase
function to form a PBR shading process.
The content of the StandardSurface
structure is as follows.
struct StandardSurface {
// albedo
vec4 albedo;
// these two need to be in the same coordinate system
vec3 position;
vec3 normal;
// emissive
vec3 emissive;
// light map
vec3 lightmap;
float lightmap_test;
// PBR params
float roughness;
float metallic;
float occlusion;
};
The example code is as below.
#include <legacy/shading-standard-base>
#include <legacy/output-standard>
void surf (out StandardSurface s) {
// fill in your data here
}
vec4 frag () {
StandardSurface s; surf(s);
vec4 color = CCStandardShadingBase(s);
return CCFragOutput(color);
}
You can refer to the builtin-standard.effect
file, and use the combination of the surf
function and the CC_STANDARD_SURFACE_ENTRY()
macro.
The CC_STANDARD_SURFACE_ENTRY()
is a wrapper that based on the render pipeline type, uses the surf
function to construct a usable main
function for the fragments. Here is an example of the code.
CCProgram shader-fs %{
#include <legacy/standard-surface-entry>
void surf (out StandardSurface s) {
// fill in your data here
}
CC_STANDARD_SURFACE_ENTRY()
}%
StandardSurface
The StandardSurface
is the structure of PBR material data that records the surface information required for lighting calculations. The surf
function in Legacy Shaders is used to fill data and it will be used during the lighting phase.
struct StandardSurface {
// albedo
vec4 albedo;
// these two need to be in the same coordinate system
HIGHP_VALUE_STRUCT_DEFINE(vec3, position);
vec3 normal;
// emissive
vec3 emissive;
// light map
vec3 lightmap;
float lightmap_test;
// PBR params
float roughness;
float metallic;
float occlusion;
float specularIntensity;
#if CC_RECEIVE_SHADOW
vec2 shadowBias;
#endif
};
ToonSurface
struct ToonSurface {
vec4 baseColor;
vec4 specular;
// these two need to be in the same coordinate system
HIGHP_VALUE_STRUCT_DEFINE(vec3, position);
vec3 normal;
// shading params
vec3 shade1;
vec3 shade2;
vec3 emissive;
float baseStep;
float baseFeather;
float shadeStep;
float shadeFeather;
float shadowCover;
#if CC_RECEIVE_SHADOW
vec2 shadowBias;
#endif
};
Similar to the StandardSurface
, the ToonSurface
is also used for surface information, but it is a structure specifically for cartoon rendering.
- Nothing to do with shaders that are not based on Mesh rendering, such as particles, Sprite, post-process, etc.↩