Importing images

Supported image formats

Godot can import the following image formats:

  • BMP (.bmp) - No support for 16-bit per pixel images. Only 1-bit, 4-bit, 8-bit, 24-bit, and 32-bit per pixel images are supported.

  • DirectDraw Surface (.dds) - If mipmaps are present in the texture, they will be loaded directly. This can be used to achieve effects using custom mipmaps.

  • OpenEXR (.exr) - Supports HDR (highly recommended for panorama skies).

  • Radiance HDR (.hdr) - Supports HDR (highly recommended for panorama skies).

  • JPEG (.jpg, .jpeg) - Doesn’t support transparency per the format’s limitations.

  • PNG (.png) - Precision is limited to 8 bits per channel upon importing (no HDR images).

  • Truevision Targa (.tga)

  • SVG (.svg, .svgz) - SVGs are rasterized using NanoSVG when importing them. Support is limited; complex vectors may not render correctly. For complex vectors, rendering them to PNGs using Inkscape is often a better solution. This can be automated thanks to its command-line interface.

  • WebP (.webp) - WebP files support transparency and can be compressed lossily or losslessly. The precision is limited to 8 bits per channel.

Note

If you’ve compiled the Godot editor from source with specific modules disabled, some formats may not be available.

Importing textures

The default action in Godot is to import images as textures. Textures are stored in video memory and can’t be accessed directly. This is what makes drawing them efficient.

Import options are vast:

../../_images/image_import1.png

Detect 3D

This option makes Godot be aware of when a texture (which is imported for 2D as default) is used in 3D. If this happens, setting are changed so the texture flags are friendlier to 3D (mipmaps, filter and repeat become enabled and compression is changed to VRAM). Texture is also reimported automatically.

Compression

Images are one of the largest assets in a game. To handle them efficiently, they need to be compressed. Godot offers several compression methods, depending on the use case.

Compress Mode

  • VRAM Compression: This is the most common compression mode for 3D assets. Size on disk is reduced and video memory usage is also decreased considerably (usually by a factor between 4 and 6). This mode should be avoided for 2D as it exhibits noticeable artifacts.

  • Lossless Compression: This is the most common compression mode for 2D assets. It shows assets without any kind of artifacting, and disk compression is decent. It will use considerably more amount of video memory than VRAM Compression, though. This is also the recommended setting for pixel art.

  • Lossy Compression: This is a good choice for large 2D assets. It has some artifacts, but less than VRAM and the file size is several times lower compared to Lossless or Uncompressed. Video memory usage isn’t decreased by this mode; it’s the same as with Lossless Compression or Uncompressed.

  • Uncompressed: Only useful for formats that can’t be compressed (such as raw float images).

In this table, each of the four options are described together with their advantages and disadvantages (good = best, bad = worst):

Uncompressed

Compress Lossless

Compress Lossy

Compress VRAM

Description

Stored as raw pixels

Stored as Lossless WebP / PNG

Stored as Lossy WebP

Stored as S3TC/BC or PVRTC/ETC depending on platform

Size on Disk

bad Large

regular Small

good Very Small

regular Small

Memory Usage

bad Large

bad Large

bad Large

good Small

Performance

regular Normal

regular Normal

regular Normal

good Fast

Quality Loss

good None

good None

regular Slight

bad Moderate

Load Time

regular Normal

bad Slow

bad Slow

good Fast

HDR Mode

Godot supports high dynamic range textures (as .HDR or .EXR). These are mostly useful as high dynamic range equirectangular panorama skies (the internet has plenty if you search for them), which replace Cubemaps in Godot 2.x. Modern PCs support the BC6H VRAM format, but there are still plenty that do not.

If you want Godot to ensure full compatibility in terms of the kind of textures, enable the “Force RGBE” option.

Normal Map

When using a texture as normal map, only the red and green channels are required. Given regular texture compression algorithms produce artifacts that don’t look that nice in normal maps, the RGTC compression format is the best fit for this data. Forcing this option to “Enabled” will make Godot import the image as RGTC compressed. By default, it’s set to “Detect”, which means that if the texture is ever used as a normal map, it will be changed to “Enabled” and reimported automatically.

Note that RGTC compression affects the resulting normal map image. You will have to adjust custom shaders that use the normal map to take this into account.

Note

Godot requires the normal map to use the X+, Y+ and Z+ coordinates, this is known as OpenGL style. If you’ve imported a material made to be used with another engine it may be DirectX style, in which case the normal map needs to be converted so its Y axis is flipped.

More information about normal maps (including a coordinate order table for popular engines) can be found here.

Flags

There are plenty of settings that can be toggled when importing an image as a texture, depending on the use case.

Repeat

This setting is most commonly used in 3D, and is therefore generally disabled in 2D. It sets UV coordinates going beyond the 0,0 - 1,1 range to “loop”.

Repeating can optionally be set to mirrored mode.

Filter

When pixels become larger than the screen pixels, this option enables linear interpolation for them. The result is a smoother (less blocky) texture. This setting can be commonly used in 2D and 3D, but it’s usually disabled when making pixel perfect games.

Mipmaps

When pixels become smaller than the screen, mipmaps kick in. This helps reduce the grainy effect when shrinking the textures. Keep in mind that, in older hardware (GLES2, mainly mobile), there are some requirements to use mipmaps:

  • Texture width and height must be powers of 2

  • Repeat must be enabled

Keep in mind the above when making phone games and applications, want to aim for full compatibility, and need mipmaps.

When doing 3D, mipmap should be turned on, as this also improves performance (smaller versions of the texture are used for objects further away).

Anisotropic

When textures are near parallel to the view (like floors), this option makes them have more detail by reducing blurriness.

sRGB

Godot uses Linear colorspace when rendering 3D. Textures mapped to albedo or detail channels need to have this option turned on in order for colors to look correct. When set to Detect mode, the texture will be marked as sRGB when used in albedo channels.

Warning

Since the texture will have its data modified when sRGB is enabled, this means using the same texture in both 2D and 3D will make the texture display with incorrect colors in either 2D or 3D.

To work around this, make a copy of the texture on the filesystem and enable sRGB on one of the copies only. Use the copy with sRGB enabled in 3D, and the copy with sRGB disabled in 2D.

Process

Some special processes can be applied to images when imported as textures.

Fix Alpha Border

This puts pixels of the same surrounding color in transition from transparency to non transparency. It helps mitigate the outline effect when exporting images from Photoshop and the like.

../../_images/fixedborder.png

It’s a good idea to leave it on by default, unless specific values are needed.

Premultiplied Alpha

An alternative to fix darkened borders is to use premultiplied alpha. By enabling this option, the texture will be converted to this format. Keep in mind that a material will need to be created that uses the PREMULT ALPHA blend mode on canvas items that need it.

HDR as sRGB

A few HDR files are broken and contain sRGB color data. It is advised not to use them, but, in the worst-case scenario, toggling this option on will make them look right.

Invert Color

Reverses the image’s color. This is useful, for example, to convert a height map generated by external programs to depth map to use with Spatial Material.

Svg

Scale

This option only applies to SVG files. It controls the scale of the SVG image. The default scale (1.0) will make the imported SVG match its original design scale.