Version: 2018.3 (switch to 2019.1 )
Built-in shader include files
Built-in shader helper functions
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Predefined Shader preprocessor macros

Unity defines several preprocessor macros when compiling Shader programs.

Target platform

Macro: Target platform:
SHADER_API_D3D11 Direct3D 11
SHADER_API_GLCORE Desktop OpenGL “core” (GL 3/4)
SHADER_API_GLES OpenGL ES 2.0
SHADER_API_GLES3 OpenGL ES 3.0/3.1
SHADER_API_METAL iOSApple’s mobile operating system. More info
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/Mac Metal
SHADER_API_VULKAN Vulkan
SHADER_API_D3D11_9X Direct3D 11 “feature level 9.x” target for Universal Windows PlatformAn IAP feature that supports Microsoft’s In App Purchase simulator, which allows you to test IAP purchase flows on devices before publishing your application. More info
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SHADER_API_PS4 PlayStation 4. SHADER_API_PSSL is also defined.
SHADER_API_XBOXONE Xbox OneMicrosoft’s eighth generation video game console.
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SHADER_API_MOBILE is defined for all general mobile platforms (GLES, GLES3, METAL).

Additionally, SHADER_TARGET_GLSL is defined when the target shading language is GLSL (always true for OpenGL/GLES platforms).

Shader target model

SHADER_TARGET is defined to a numeric value that matches the ShaderA small script that contains the mathematical calculations and algorithms for calculating the Color of each pixel rendered, based on the lighting input and the Material configuration. More info
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target compilation model (that is, matching #pragma target directive). For example, SHADER_TARGET is 30 when compiling into Shader model 3.0. You can use it in Shader code to do conditional checks. For example:

#if SHADER_TARGET < 30
    // less than Shader model 3.0:
    // very limited Shader capabilities, do some approximation
#else
    // decent capabilities, do a better thing
#endif

Unity version

UNITY_VERSION contains the numeric value of the Unity version. For example, UNITY_VERSION is 501 for Unity 5.0.1. This can be used for version comparisons if you need to write Shaders that use different built-in Shader functionality. For example, a #if UNITY_VERSION >= 500 preprocessor check only passes on versions 5.0.0 or later.

Shader stage being compiled

Preprocessor macros SHADER_STAGE_VERTEX, SHADER_STAGE_FRAGMENT, SHADER_STAGE_DOMAIN, SHADER_STAGE_HULL, SHADER_STAGE_GEOMETRY, SHADER_STAGE_COMPUTE are defined when compiling each Shader stage. Typically they are useful when sharing Shader code between pixelThe smallest unit in a computer image. Pixel size depends on your screen resolution. Pixel lighting is calculated at every screen pixel. More info
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Shaders and compute Shaders, to handle cases where some things have to be done slightly differently.

Platform difference helpers

Direct use of these platform macros is discouraged, as they don’t always contribute to the future-proofing of your code. For example, if you’re writing a Shader that checks for D3D11, you may want to ensure that, in the future, the check is extended to include Vulkan. Instead, Unity defines several helper macros (in HLSLSupport.cginc):

Macro: Use:
UNITY_BRANCH Add this before conditional statements to tell the compiler that this should be compiled into an actual branch. Expands to [branch] when on HLSL platforms.
UNITY_FLATTEN Add this before conditional statements to tell the compiler that this should be flattened to avoid an actual branch instruction. Expands to [flatten] when on HLSL platforms.
UNITY_NO_SCREENSPACE_SHADOWS Defined on platforms that do not use cascaded screenspace shadowmaps (mobile platforms).
UNITY_NO_LINEAR_COLORSPACE Defined on platforms that do not support Linear color space (mobile platforms).
UNITY_NO_RGBM Defined on platforms where RGBM compressionA method of storing data that reduces the amount of storage space it requires. See Texture Compression3D Graphics hardware requires Textures to be compressed in specialised formats which are optimised for fast Texture sampling. More info
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, Animation CompressionThe method of compressing animation data to significantly reduce file sizes without causing a noticable reduction in motion quality. Animation compression is a trade off between saving on memory and image quality. More info
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, Audio Compression, Build Compression.
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for lightmapsA pre-rendered texture that contains the effects of light sources on static objects in the scene. Lightmaps are overlaid on top of scene geometry to create the effect of lighting. More info
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is not used (mobile platforms).
UNITY_NO_DXT5nm Defined on platforms that do not use DXT5nm normal-map compression (mobile platforms).
UNITY_FRAMEBUFFER_FETCH_AVAILABLE Defined on platforms where “framebuffer color fetch” functionality can be available (generally iOS platforms - OpenGL ES 2.0, 3.0 and Metal).
UNITY_USE_RGBA_FOR_POINT_SHADOWS Defined on platforms where point light shadowmaps use RGBA Textures with encoded depth (other platforms use single-channel floating point Textures).
UNITY_ATTEN_CHANNEL Defines which channel of light attenuation Texture contains the data; used in per-pixel lighting code. Defined to either ‘r’ or ‘a’.
UNITY_HALF_TEXEL_OFFSET Defined on platforms that need a half-texel offset adjustment in mapping texels to pixels (e.g. Direct3D 9).
UNITY_UV_STARTS_AT_TOP Always defined with value of 1 or 0. A value of 1 is on platforms where Texture V coordinate is 0 at the “top” of the Texture. Direct3D-like platforms use value of 1; OpenGL-like platforms use value of 0.
UNITY_MIGHT_NOT_HAVE_DEPTH_Texture Defined if a platform might emulate shadow maps or depth Textures by manually renderingThe process of drawing graphics to the screen (or to a render texture). By default, the main camera in Unity renders its view to the screen. More info
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depth into a Texture.
UNITY_PROJ_COORD(a) Given a 4-component vector, this returns a Texture coordinate suitable for projected Texture reads. On most platforms this returns the given value directly.
UNITY_NEAR_CLIP_VALUE Defined to the value of near clipping planeA plane that limits how far or close a camera can see from its current position. A camera’s viewable range is between the far and near clipping planes. See far clipping plane and near clipping plane. More info
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. Direct3D-like platforms use 0.0 while OpenGL-like platforms use –1.0.
UNITY_VPOS_TYPE Defines the data type required for pixel position input (VPOS): float2 on D3D9, float4 elsewhere.
UNITY_CAN_COMPILE_TESSELLATION Defined when the Shader compiler “understands” the tessellation Shader HLSL syntax (currently only D3D11).
UNITY_INITIALIZE_OUTPUT(type,name) Initializes the variable name of given type to zero.
UNITY_COMPILER_HLSL, UNITY_COMPILER_HLSL2GLSL, UNITY_COMPILER_CG Indicates which Shader compiler is being used to compile Shaders - respectively: Microsoft’s HLSL, HLSL to GLSL translator, and NVIDIA’s Cg. See documentation on Shading Languages for more details. Use this if you run into very specific Shader syntax handling differences between the compilers, and want to write different code for each compiler.
  • UNITY_REVERSED_Z - defined on plaftorms using reverse Z buffer. Stored Z values are in the range 1..0 instead of 0..1.

Shadow mapping macros

Declaring and sampling shadow maps can be very different depending on the platform. Unity has several macros to help with this:

Macro: Use:
UNITY_DECLARE_SHADOWMAP(tex) Declares a shadowmap Texture variable with name “tex”.
UNITY_SAMPLE_SHADOW(tex,uv) Samples shadowmap Texture “tex” at given “uv” coordinate (XY components are Texture location, Z component is depth to compare with). Returns single float value with the shadow term in 0..1 range.
UNITY_SAMPLE_SHADOW_PROJ(tex,uv) Similar to above, but does a projective shadowmap read. “uv” is a float4, all other components are divided by .w for doing the lookup.

NOTE: Not all graphics cards support shadowmaps. Use SystemInfo.SupportsRenderTextureFormat to check for support.

Constant buffer macros

Direct3D 11 groups all Shader variables into “constant buffers”. Most of Unity’s built-in variables are already grouped, but for variables in your own Shaders it might be more optimal to put them into separate constant buffers depending on expected frequency of updates.

Use CBUFFER_START(name) and CBUFFER_END macros for that:

CBUFFER_START(MyRarelyUpdatedVariables)
    float4 _SomeGlobalValue;
CBUFFER_END

Texture/Sampler declaration macros

Usually you would use texture2D in Shader code to declare a Texture and Sampler pair. However on some platforms (such as DX11), Textures and Samplers are separate GameObjectsThe fundamental object in Unity scenes, which can represent characters, props, scenery, cameras, waypoints, and more. A GameObject’s functionality is defined by the Components attached to it. More info
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, and maximum possible Sampler count is quite limited. Unity has some macros to declare Textures without Samplers, and to sample a Texture using a Sampler from another Texture. Use this if you end up running into Sampler limits, and you know that several of your Textures can in fact share a Sampler (Samplers define Texture filtering and wrapping modes).

Macro: Use:
UNITY_DECLARE_TEX2D(name) Declares a Texture and Sampler pair.
UNITY_DECLARE_TEX2D_NOSAMPLER(name) Declares a Texture without a Sampler.
UNITY_DECLARE_TEX2DARRAY(name) Declares a Texture array Sampler variable.
UNITY_SAMPLE_TEX2D(name,uv) Sample from a Texture and Sampler pair, using given Texture coordinate.
UNITY_SAMPLE_TEX2D_SAMPLER( name,samplername,uv) Sample from Texture (name), using a Sampler from another Texture (samplername).
UNITY_SAMPLE_TEX2DARRAY(name,uv) Sample from a Texture array with a float3 UV; the z component of the coordinate is array element index.
UNITY_SAMPLE_TEX2DARRAY_LOD(name,uv,lod) Sample from a Texture array with an explicit mipmap level.

For more information, see documentation on Sampler States.

Surface Shader pass indicators

When Surface ShadersUnity’s code generation approach that makes it much easier to write lit shaders than using low level vertex/pixel shader programs. More info
See in Glossary
are compiled, they generate a lot of code for various passes to do lighting. When compiling each pass, one of the following macros is defined:

Macro: Use:
UNITY_PASS_FORWARDBASE Forward renderingA rendering path that renders each object in one or more passes, depending on lights that affect the object. Lights themselves are also treated differently by Forward Rendering, depending on their settings and intensity. More info
See in Glossary
base pass (main directional light, lightmaps, SH).
UNITY_PASS_FORWARDADD Forward rendering additive pass (one light per pass).
UNITY_PASS_DEFERRED Deferred shadingA rendering path that places no limit on the number of lights that can affect a GameObject. All lights are evaluated per-pixel, which means that they all interact correctly with normal maps and so on. Additionally, all lights can have cookies and shadows. More info
See in Glossary
pass (renders g buffer).
UNITY_PASS_SHADOWCASTER Shadow caster and depth Texture rendering pass.
UNITY_PASS_PREPASSBASE Legacy deferred lighting base pass (renders normals and specular exponent).
UNITY_PASS_PREPASSFINAL Legacy deferred lighting final pass (applies lighting and Textures).

Disable Auto-Upgrade

UNITY_SHADER_NO_UPGRADE allows you to disable Unity from automatically upgrading or modifying your shader file.

See also


• 2017–05–16 Page amended with no editorial review

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