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Effective ASTC Encoding

Most texture compression schemes encode a single color format at single bitrate, so there are relatively few configuration options available to content creators beyond selecting which compressed format to use.

ASTC on the other hand is an extremely flexible container format which can compress multiple color formats at multiple bit rates. Inevitably this flexibility gives rise to questions about how to best use ASTC to encode a specific color format, or what the equivalent settings are to get a close match to another compression format.

This page aims to give some guidelines, but note that they are only guidelines and are not exhaustive so please deviate from them as needed.

Traditional format reference

The most commonly used non-ASTC compressed formats, their color format, and their compressed bitrate are shown in the table below.

Name Color Format Bits/Pixel Notes
BC1 RGB+A 4 RGB565 + 1-bit A
BC3 RGB+A 8 BC1 RGB + BC4 A
BC3nm G+R 8 BC1 G + BC4 R
BC4 R 4 L8
BC5 R+G 8 BC1 R + BC1 G
BC6H RGB (HDR) 8
BC7 RGB / RGBA 8
EAC_R11 R 4 R11
EAC_RG11 RG 8 RG11
ETC1 RGB 4 RGB565
ETC2 RGB+A 4 RGB565 + 1-bit A
ETC2+EAC RGB+A 8 RGB565 + EAC A
PVRTC RGBA 2 or 4

Note: BC2 (RGB+A) is not included in the table because it's rarely used in practice due to poor quality alpha encoding; BC3 is nearly always used instead.

Note: Color representations shown with a + symbol indicate non-correlated compression groups; e.g. an RGB + A format compresses RGB and A independently and does not assume the two signals are correlated. This can be a strength (it improves quality when compressing non-correlated signals), but also a weakness (it reduces quality when compressing correlated signals).

ASTC Format Mapping

The main question which arises with the mapping of another format on to ASTC is how to handle cases where the input isn't a 4 component RGBA input. ASTC is a container format which always decompresses in to a 4 component RGBA result. However, the internal compressed representation is very flexible and can store 1-4 components as needed on a per-block basis.

To get the best quality for a given bitrate, or the lowest bitrate for a given quality, it is important that as few components as possible are stored in the internal representation to avoid wasting coding space.

Specific optimizations in the ASTC coding scheme exist for:

  • Encoding the RGB components as a single luminance component, so only a single value needs to be stored in the coding instead of three.
  • Encoding the A component as a constant 1.0 value, so the coding doesn't actually need to store a per-pixel alpha value at all.

... so mapping your inputs given to the compressor to hit these paths is really important if you want to get the best output quality for your chosen bitrate.

Encoding 1-4 component data

The table below shows the recommended component usage for data with different numbers of color components present in the data.

The coding swizzle should be applied when compressing an image. This can be handled by the compressor when reading an uncompressed input image by specifying the swizzle using the -esw command line option.

The sampling swizzle is what your should use in your shader programs to read the data from the compressed texture, assuming no additional API-level component swizzling is specified by the application.

Input components ASTC Endpoint Coding Swizzle Sampling Swizzle
1 L + 1 rrr1 .g 1
2 L + A rrrg .ga 1
3 RGB + 1 rgb1 .rgb
4 RGB + A rgba .rgba

1: Sampling from g is preferred to sampling from r because it allows a single shader to be compatible with ASTC, BC1, or ETC formats. BC1 and ETC1 store color endpoints as RGB565 data, so the g component will have higher precision. For ASTC it doesn't actually make any difference; the same single component luminance will be returned for all three of the .rgb components.

Equivalence with other formats

Based on these component encoding requirements we can now derive the the ASTC coding equivalents for most of the other texture compression formats in common use today.

Formant ASTC Coding Swizzle ASTC Sampling Swizzle Notes
BC1 rgba 1 .rgba
BC3 rgba .rgba
BC3nm gggr .ag
BC4 rrr1 .r
BC5 rrrg .ra 2
BC6H rgb1 .rgb 3 HDR profile only
BC7 rgba .rgba
EAC_R11 rrr1 .r
EAC_RG11 rrrg .ra 2
ETC1 rgb1 .rgb
ETC2 rgba 1 .rgba
ETC2+EAC rgba .rgba
ETC2+EAC rgba .rgba

1: ASTC has no equivalent of the 1-bit punch-through alpha encoding supported by BC1 or ETC2; if alpha is present it will be a full alpha component.

2: ASTC relies on using the L+A color endpoint type for coding efficiency for two component data. It therefore has no direct equivalent of a two-plane format sampled though the .rg components such as BC5 or EAC_RG11. This can be emulated by setting texture component swizzles in the runtime API - e.g. via glTexParameteri() for OpenGL ES - although it has been noted that API controlled swizzles are not available in WebGL.

3: ASTC can only store unsigned values, and has no equivalent of the BC6 signed endpoint mode.

Other Considerations

This section outlines some of the other things to consider when encoding textures using ASTC.

Decode mode extensions

ASTC is specified to decompress into a 16-bit per component RGBA output by default, with the exception of the sRGB format which uses an 8-bit value for the RGB components.

Decompressing in to a 16-bit per component output format is often higher than many use cases require, especially for LDR textures which originally came from an 8-bit per component source image. Most implementations of ASTC support the decode mode extensions, which allow an application to opt-in to a lower precision decompressed format (RGBA8 for LDR, RGB9E5 for HDR). Using these extensions can improve GPU texture cache efficiency, and even improve texturing filtering throughput, for use cases that do not need the higher precision.

The ASTC format uses different data rounding rules when the decode mode extensions are used. To ensure that the compressor chooses the best encodings for the RGBA8 rounding rules, you can specify -decode_unorm8 when compressing textures that will be decompressed into the RGBA8 intermediate. This gives a small image quality boost.

Note: This mode is automatically enabled if you use the astcenc decompressor to write an 8-bit per component output image.

Encoding non-correlated components

Most other texture compression formats have a static component assignment in terms of the expected data correlation. For example, ETC2+EAC assumes that RGB are always correlated and that alpha is non-correlated. ASTC can automatically encode data as either fully correlated across all 4 components, or with any one component assigned to a separate non-correlated partition to the other three.

The non-correlated component can be changed on a block-by-block basis, so the compressor can dynamically adjust the coding based on the data present in the image. This means that there is no need for non-correlated data to be stored in a specific component in the input image.

It is however worth noting that the alpha component is treated differently to the RGB color components in some circumstances:

  • When coding for sRGB the alpha component will always be stored in linear space.
  • When coding for HDR the alpha component can optionally be kept as LDR data.

Encoding normal maps

The best way to store normal maps using ASTC is similar to the scheme used by BC5; store the X and Y components of a unit-length normal. The Z component of the normal can be reconstructed in shader code based on the knowledge that the vector is unit length.

To encode this we need to store only two input components in the compressed data, and therefore use the rrrg coding swizzle to align the data with the ASTC luminance+alpha endpoint. We can sample this in shader code using the .ga sampling swizzle, and reconstruct the Z value with:

vec3 nml;
nml.xy = texture(...).ga;                // Load normals (range 0 to 1)
nml.xy = nml.xy * 2.0 - 1.0;             // Unpack normals (range -1 to +1)
nml.z = sqrt(1 - dot(nml.xy, nml.xy));   // Compute Z, given unit length

The encoding swizzle and appropriate component weighting is enabled by using the -normal command line option. If you wish to use a different pair of components you can specify a custom swizzle after setting the -normal parameter. For example, to match BC5n component ordering use -normal -esw gggr for compression and -normal -dsw arz1 for decompression.

Encoding sRGB data

The ASTC LDR profile can compress sRGB encoded color, which is a more efficient use of bits than storing linear encoded color because the gamma corrected value distribution more closely matches human perception of luminance.

For color data it is nearly always a perceptual quality win to use sRGB input source textures that are then compressed using the ASTC sRGB compression mode (compress using the -cs command line option rather than the -cl command line option). Note that sRGB gamma correction is only applied to the RGB components during decode; the alpha component is always treated as linear encoded data.

Important: The uncompressed input texture provided on the command line must be stored in the sRGB color space for -cs to function correctly.

Encoding HDR data

HDR data can be encoded just like LDR data, but with some caveats around handling the alpha component.

For many use cases the alpha component is an actual alpha opacity component and is therefore used for storing an LDR value between 0 and 1. For these cases use the -ch compressor option which will treat the RGB components as HDR, but the A component as LDR.

For other use cases the alpha component is simply a fourth data component which is also storing an HDR value. For these cases use the -cH compressor option which will treat all components as HDR data.


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