Gingerbread is a set of Python utilities used by Winterbloom
Project description
🍪 Gingerbread
Gingerbread is a set of Python utilities used by Winterbloom to create decorative printed circuit boards (PCBs), such as the ones we used a front panels:
Gingerbread consists of three utilities:
convert
helps convert designs created with Affinity Designer to KiCAD PCB files.fancytext
is used to generate beautiful text labels for KiCAD PCBs.trace
is a re-implementation of KiCAD's "Image Converter" program (bitmap2component) as a Python library and command line tool to enable automation.
NOTE: This tool is extremely tailored to Winterbloom's needs. It's not perfect, it's not universal, and it probably won't work the way you think it will. Because of this, it comes with no warranty and no promise of support- again, we won't be providing any free support for this.
That said, you're welcome to try it out, learn from it, take code from it, and give us feedback or even contribute if you'd like. If you'd like to pay us to add a feature or support some use case, reach out.
There are several similar projects that might fit your use case better.
Installation
Presently we've only ever tested on macOS and Linux. It might be tricky to get working regardless of platform, and it probably doesn't work on Windows except under WSL. There's a Docker option, but it has some drawbacks.
macOS
You'll need homebrew and a few dependencies:
brew install cairo pango pangocairo potrace
You'll also need Python 3.10 or later. Install using pip
:
python3 -m pip install gingerbread
Linux / WSL
At the time of writing, Ubuntu 22.04 or later is your best bet. If you want to use Debian, you'll need to build Python 3.10 or later and pango 1.50 or later, since the current versions are behind. This should work under WSL (Windows Subsystem for Linux), just be sure to use Ubuntu 22.04 or later.
You'll need at least the following system packages:
sudo apt install -y \
build-essential \
cmake \
libpotrace-dev \
libvips-dev \
libcairo2 \
libpango1.0-0 \
libpangocairo-1.0-0 \
libvips42
Once you have the requisites installed, you can install Gingerbread:
python3 -m pip install --user gingerbread
Docker
There's a rough Docker version of Gingerbread that you can use if all else fails. From our limited testing, convert
works okay (although a bit slower), but fancytext
does not work at all.
To use the Docker version, clone this repo:
git clone https://github.com/wntrblm/Gingerbread.git
cd Gingerbread
Build the image- we don't publish it to Dockerhub because it's experimental:
docker build -t gingerbread .
You can now run Gingerbread using Docker. You'll need to pass the current working directory as a volume so that Gingerbread can read and write files. You can test this out on the included example file:
cd example
docker run --rm -v "$PWD":/workdir gingerbread -m gingerbread.convert example.svg
Using convert
convert
is designed to convert designs created with Affinity Designer to KiCAD PCB files. convert
requires a bit of work to set up, but once working you can rapidly iterate on your design.
There's an example in the ./example
directory, including the source afdesign
file, the exported svg
, and the generated kicad_pcb
. It might be useful to look at the example as you work through these docs.
Page settings
It's highly recommended to set up your document in Affinity to use millimeters and to have a DPI of 2540
:
Why that specific DPI? Well, 2540 DPI happens to be 1000 dots-per-mm, which helpfully avoids rounding issues when exporting the design from Affinity and when converting the outline and drills. You can use other DPIs, just be sure to tell convert
using the --dpi
flag.
Creating an outline
The outline should be drawn on a layer named Edge.Cuts
(or EdgeCuts
) in Affinity. convert
handles Edge.Cuts
in a specific way to make sure that there is a 1-to-1 match between the size and units in Affinity and KiCAD. This approach can't handle as many complex edge cases as the rasterization approach used by the graphic layers, but as long as your paths have been converted to curves it should handle them well. Edge.Cuts
can also contain "cut-outs"- closed paths within the overall board shape.
The example file has a complex outline with four internal cut-outs.
Graphics layers
Non-transparent areas on layers F.SilkS
, B.SilkS
, F.Cu
, and B.Cu
in Affinity are converted as-is to the respective layers in KiCAD. F.Mask
and B.Mask
are "inverted" like they are in KiCAD, meaning that non-transparent areas indicate where to remove the soldermask. For all of these layers, convert
works by rasterizing the individual layers to black and white images, re-vectorizing using trace
, and plotting the results as a KiCAD footprint.
The example file has graphics on the F.SilkS
, F.Cu
, and F.Mask
layers.
Drills
Items on the Drills
layer are handled seperately as well. convert
walks through all of the shapes in the Drills
layer and converts only circles to drills. This is again done to preserve position and size between Affinity and KiCAD.
The example file has a single drill in the center.
Exporting the design
When exporting the design to an SVG, click the More button and setup the export parameters. Make sure that Rasterize is set to "Nothing", Export text as curves is checked, and Flatten transforms is checked.
You can save this as a preset to avoid having to change these every time you export.
Running convert
Once the design is exported as an SVG, you can run convert
to turn it into a KiCAD PCB:
python3 -m gingerbread.convert design.svg
convert
will report details about the converted PCB. Double-check this output to make sure that things match up with what you expect. For example. running convert on the example design shows:
convert: Converting board outline
convert: Outline converted: overall board size is 100.00 mm x 100.00 mm (10000.00 mm²).
convert: Converting drills
convert: Drills converted: 1
convert: Converting graphic layers
convert: F.SilkS converted
convert: B.SilkS not found
convert: F.Cu converted
convert: B.Cu not found
convert: F.Mask converted
convert: B.Mask not found
convert: Writing...
convert: Written to example.kicad_pcb 💜
convert
has a several options for customizing the conversion process and the output. Run python3 -m gingerbread.convert --help
to get a full list of options.
Using fancytext
fancytext
is intended to be relatively easy to use. It's a terminal application that copies the resulting label to your clipboard.
The most basic example is:
python3 -m gingerbread.fancytext "example"
Which will generate a simple text label:
This rudimentary example isn't much more useful than KiCAD's own text facilities, but Fancytext gives you much more control.
You can change various aspects of how the text is rendered:
python3 -m gingerbread.fancytext --font "Pluto" --italic --size 3 "example"
You can run python3 -m gingerbread.fancytext --help
to get a complete list of options.
Fancytext has another fancy trick- outlines. You can use outlines to call more attention to your text labels. There are various outline styles, starting with --outline-stroke
:
python3 -m gingerbread.fancytext --outline-stroke 0.5 "example"
There's also the more eye-catching --outline-fill
:
python3 -m gingerbread.fancytext --outline-fill --outline-stroke 0.2 "example"
The shape of the end caps can be changed by wrapping your text in []
, ||
, <>
, ()
, //
, or \\
, and you can mix and match:
python3 -m gingerbread.fancytext --outline-fill --outline-stroke 0.2 "/example>"
There are lots of options for customizing the look of these labels. You can run python3 -m gingerbread.fancytext --help
to get a complete list of options. As an example, we like using these settings for our labels:
python3 -m gingerbread.fancytext --font "Space Mono" --bold --italic --stroke 0.1 --padding 0 0 --outline-stroke 0.2 --outline-fill "fancytext"
Which ends up looking like this:
Using trace
trace
is fairly straightforward compared to the other tools in Gingerbread. Provide it with an image and it will provide you with a KiCAD footprint:
python3 -m gingerbread.trace footprint.png
There's several options for trace
, including the important --dpi
option which tells trace
the physical size that the footprint should be. Run python3 -m gingerbread.trace --help
see all options.
Similar projects
Projects similar to Gingerbread's convert
:
- svg2shenzhen is an Inkscape-based tool for creating PCBs and footprints from SVGs. Gingerbread shares a lot in common with svg2shenzhen's inner workings, but svg2shenzhen is much more broadly used and handles more use cases.
- Gerbolyze renders both vector and raster artwork onto existing Gerber files. This is a very different approach than the one taken by Gingerbread and svg2shenzhen and can produce some incredible results through its grayscale emulation.
- PCBmodE is a circuit board design program built on Inkscape.
Projects similar to Fancytext:
- KiBuzzard creates beautiful text labels. Fancytext is actually inspired by and inherits many stylistic choices from Buzzard. However, they differ in their implementation - Buzzard is vector graphics all the way through, whereas Fancytext has an intermediary rasterization step. KiBuzzard is also a KiCAD plugin with a GUI whereas Fancytext is (presently) a terminal application.
Acknowledgements
Gingerbread sits on the shoulders of the incredible work of other open source projects:
- cairosvg is used by
convert
to rasterize SVG files. - cairo (via cairocffi) is used by both
convert
andfancytext
to render 2d graphics. - pango (via pangocffi) is used by
fancytext
to layout text. - svgpathtools is used by
convert
to process the board outline. - rich is used throughout for pretty terminal output.
- pyperclip is used to copy stuff to your clipboard.
- numpy is used extensively to shuffle data around between various libraries.
- vips (via pyvips) is used for processing images efficiently.
- potrace (via potracecffi) is used in
trace
for converting raster images to polygons. - Gdsdk and the underlying Clipper library are used to wrangle polygons and punch holes in them.
Additionally, information and ideas from the following projects were used when building Gingerbread:
- svg2shenzhen's overall strategy for converting SVGs to KiCAD PCBs served as the starting point for Gingerbread's
convert
. - pangocairocffi's tests were used as a starting point when implementing
fancytext
's text layout. - librsvg's text.rs was used as a reference for implementing
fancytext
's text layout. - KiCAD's bitmap2component was used as a reference for implementing
trace
and for testing its output. - KiCAD's kimath was used as a reference for implementing
trace
's polygon handling. - KiCAD's S-Expression reference.
Contributing
Because this tool is so specifically tailored to Winterbloom's workflow, we aren't really expecting a lot of outside contributions. However, if you'd like to contribute please file an issue or reach out to us before you start writing code, so we can make sure it's something that'll be beneficial for all of us. :)
License
Gingerbread is published under the MIT License
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