three-pixel-font
A pixel font mesh/material for three.js
This pixel-font rendering toolkit takes a glyph texture, and a couple simple text files for configuration. It uses pixel-columns as a basis for rendering text with variable width, and supports one layer of overlap, on characters that need to share space.
example
const textMesh = new PixelTextMesh("Hello World.", {
fontFace: new PixelFontFace("path/to/cdogs_font_7x8"),
color: new Color(1, 1, 1),
letterSpacing: -1,
strokeColor: new Color(0, 0, 0),
scaleDownToPhysicalSize: true,
screenSpace: false,
constantSizeOnScreen: false
}, undefined, (w, h) => {
book.scale.x = 0.01 * w
book.scale.y = 0.01 * h
})
this.scene.add(textMesh)
font format
A font needs 3 parts
-
a glyph texture png
-
a glyph txt file
-
a char width txt file
They must be similarly named, like this:
path/to/fonts/testFont.png
path/to/fonts/testFont.txt
path/to/fonts/testFont_char-widths.txt
Approach and History
Originally it was a very simple approach to pixel font rendering:
A block of text would be comprised of a font glyph texture, and a layout texture. The layout texture was a single-channel 8bit texture where each pixel's value was literally the glyph index.
This was great for fixed-width fonts, but legibility suffered.
The algorithm was extended to treat every pixel of width of a character as a distinct lookup. Fonts are still fixed-height, but each pixel column of text is no longer locked to a glyph grid.
The layout texture grew significantly to accomidate this. A single character used to be 1 8bit value, but now a single character needs a glyph index and a pixel offset for each column of pixels.
A 7 pixel wide glyph now needed 7 * 2 * 8bit of data on the layout texture. For WebGL 1.0 compatibility reasons, the layout texture was made 4-channel, not the minimal 2-channel needed.
Inspired by fonts like C-Dogs by Ronny Wester, outlines in the font actually look best when they are overlapping (maximum).
The final upgrade to the algorithm was to use the final unused 2 channels of the layout texture's 4 channels, to provide an alternate glyph column.
Every column of the final text can sample two different glyph columns and max them.
Limitations
Boundaries between pixels in the final render tend to resolve to the incorrect neighbour, creating pixel-thin artifacts.
The font data, and the loading thereof, is very opinionated, and subject to change. Right now, the font faces are hard-coded in the library (CDogs 7x8 only), but it's designed to only load upon usage.
Currently, the font char-widths txt file store one number per glyph, which represents how much narrower the glyph is than the max width. This is just a practical hack to keep the indices of glyphs identical to the width, in their repective txt files. This proved useful when working on a font 11 pixels wide, but whose narrowest character is 4 pixels wide. The width-difference for that character was 7, a single-digit value.