Version: 2022.3
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Built-in shader variables
Using sampler states

Shader data types and precision

Unity uses the standard ShaderA program that runs on the GPU. More info
See in Glossary
language HLSL and supports general HLSL data types. However, Unity handles some data types differently from HLSL to provide better support on mobile platforms.

Basic data types

Shaders carry out the majority of calculations using floating point numbers (also called as float in regular programming languages like C#). In Unity’s implementation of HLSL, the scalar floating point data types are float, half, and fixed. These data types differ in precision and, consequently, performance or power usage. There are also several related data types for vectors and matrices such as half3 and float4x4.

High precision: float

This is the highest precision floating point data type. On most platforms, float values are 32 bits like in regular programming languages.

Full float precision is typically useful for world space positions, texture coordinates, or scalar calculations that involve complex functions such as trigonometry or power/exponentiation. If you use lower precision floating point data types for these purposes, it can cause precision-related artifacts. For example with texture coordinates, a half doesn’t have enough precision to accurately represent 1-texel offsets of larger textures.

Medium precision: half

This is a medium precision floating point data type. On platforms that support half values, they’re generally 16 bits. On other platforms, this becomes float.

half values have a smaller range and precision than float values.

Half precision is useful to get better shader performance for values that don’t require high precision such as short vectors, directions, object space positions, and high dynamic range colors.

Low precision: fixed

This is only supported by the OpenGL ES 2.0 Graphics API. On other APIs it becomes the lowest supported precision (half or float).

This is the lowest precision fixed point value and is generally 11 bits. fixed values range from –2.0 to +2.0 and have a precision of 1/256.

Fixed precision is useful for regular colors (that are typically stored in regular textures) and performing simple operations on them.

Floating point numbers

Unity’s shader compiler ignores floating point number suffixes from HLSL. Floating point numbers with a suffix therefore all become float.

This code shows a possible negative impact of numbers with the h suffix in Unity: half3 packedNormal = ...; half3 normal = packedNormal * 2.0h - 1.0h;

Since the h suffix is ignored, the shader compiler generates code that executes these steps: 1. Calculate an intermediary normal value in high precision (float3) 2. Convert the intermediary value to half3. This reduces your shader’s performance.

This code is more efficient because it only uses half values in its calculations: half3 packedNormal = ...; half3 normal = packedNormal * half(2.0) - half(1.0);

Floating point numbers

Unity’s shader compiler ignores floating point number suffixes from HLSL. Floating point numbers with a suffix therefore all become float.

This code shows a possible negative impact of numbers with the h suffix in Unity: half3 packedNormal = ...; half3 normal = packedNormal * 2.0h - 1.0h;

Since the h suffix is ignored, the shader compiler generates code that executes these steps: 1. Calculate an intermediary normal value in high precision (float3) 2. Convert the intermediary value to half3. This reduces your shader’s performance.

This code is more efficient because it only uses half values in its calculations: half3 packedNormal = ...; half3 normal = packedNormal * half(2.0) - half(1.0);

Integer data types

Integers (int data type) are often used as loop counters or array indices, and typically work fine across various platforms.

Depending on the platform you’ve chosen, your GPU might not support integer types. For example, OpenGL ES 2.0 GPUs only operate on floating point data, and might need complicated floating point math instructions to emulate simple-looking integer expressions that involves bit or logical operations.

Direct3D 11, OpenGL ES 3, Metal, and other modern platforms have proper support for integer data types, so using bit shifts and bit masking works as expected.

Composite vector/matrix types

HLSL has built-in vector and matrix types are created from the basic types. For example, float3 is a 3D vector with .x, .y, .z components, and half4 is a medium precision 4D vector with .x, .y, .z, .w components. Alternatively, you can index vectors using .r, .g, .b, .a components, which is useful when working on colors. For example:

float4 myColor = ...
float redValue = myColor.r;

Matrix types are built in a similar way; for example float4x4 is a 4x4 transformation matrix. However, some platforms like OpenGL ES 2.0 only support square matrices.

Texture/Sampler types

Typically, you declare textures in your HLSL code in the following way:

sampler2D _MainTex;
samplerCUBE _Cubemap;

For mobile platforms, these translate into low precision samplers, that is, the textures should have low precision data in them. You can change the default sampler precision for the whole Unity project in the Player SettingsSettings that let you set various player-specific options for the final game built by Unity. More info
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using the Shader precision model dropdown. If you know your texture contains HDRhigh dynamic range
See in Glossary
colors, you might want to use half precision sampler:

sampler2D_half _MainTex;
samplerCUBE_half _Cubemap;

Or if your texture contains full float precision data depth texture, use a full precision sampler:

sampler2D_float _MainTex;
samplerCUBE_float _Cubemap;

Precision, hardware support and performance

As PC (Windows/Mac/Linux) GPUs are always of high precision, it doesn’t matter whether you write float, half or fixed data types in your shaders. They always calculate everything in full 32-bit floating point precision.

The half and fixed types only become relevant when targeting mobile GPUs, where these types primarily exist for power and performance constraints. Make sure to test your shaders on mobile to check for any precision/numerical issues.

Even on mobile GPUs, the different precision support varies between GPU families. Here’s an overview of how each mobile GPU family treats each floating point type (indicated by the number of bits used for it):

GPU Family float half fixed
PowerVR Series 6/7 32 16
PowerVR SGX 5xx 32 16 11
Qualcomm Adreno 4xx/3xx 32 16
Qualcomm Adreno 2xx 32 vertex 24 fragment
ARM Mali T6xx/7xx 32 16
ARM Mali 400/450 32 vertex 16 fragment
NVIDIA X1 32 16
NVIDIA K1 32
NVIDIA Tegra 3/4 32 16

Most modern mobile GPUs actually only support either 32-bit numbers (used for float type) or 16-bit numbers (used for both half and fixed types). Some older GPUs have different precisions for vertex shaderA program that runs on each vertex of a 3D model when the model is being rendered. More info
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and fragment shader computations.

Using lower precision can often be faster, either due to improved GPU register allocation, or due to special “fast path” execution units for certain lower-precision math operations. Even when there’s no raw performance advantage, using lower precision often uses less power on the GPU, leading to better battery life.

Unity recommends to start with half precision for everything except positions and texture coordinates. Increase precision only if half precision isn’t enough for some parts of the computation.

Support for infinities, NaNs and other special floating point values

Support for special floating point values can be different depending on which GPU family (mostly mobile) you’re running.

All PC GPUs that support Direct3D 10 support well-specified IEEE 754 floating point standard. This means that float numbers behave exactly like they do in regular programming languages on the CPU.

Mobile GPUs can have slightly different levels of support. On some, dividing zero by zero might result in a NaN (“not a number”); on others it might result in infinity, zero or any other unspecified value. Make sure to test your shaders on the target device to check they’re supported.

External GPU documentation

GPU vendors have in-depth guides about the performance and capabilities of their GPUs. See these for details:

Additional resources:

Built-in shader variables
Using sampler states
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