Skip to content

DanielVandH/TriangulArt.jl

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

44 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

TriangulArt

Build Status

Transform an image into to a low-resolution artistic version using Delaunay Triangulation.

This package is a learning exercise for me. YMMV. Some behind-the-scenes details are in this blog post.

This began life as a Julia port of this Python-based script by Iain Barr, but will likely diverge as time goes on.

Installation

julia> Pkg.add("https://github.com/jonocarroll/TriangulArt.jl")

Important

TriangulArt requires the python package scikit-image be installed and available to PyCall.

Usage

To use this package, load an image then call triangulArt() on it

using FileIO
using TriangulArt

bird = load("examples/bird_small.jpg")

A "fast" version samples entirely randomly,and likely produces poor results

triangulArt(bird, npts=500, fast=true)

Instead, using entropy-based sampling is slower, but produces better results with fewer points (default 100)

triangulArt(bird)

everest = load("examples/everest.jpeg")

triangulArt(everest)

A small number of named options are available, including:

  • npts=100: change the number of points to be sampled from the entropy
  • fast=false: use a "fast" algorithm selecting points randomly, or a "slow" entropy-based algorithm
  • refine=false: use the DelaunayTriangulation refine method to add more triangles where possible
  • debug=false: draw the sampled points and edges explicitly
  • showimage=true: show a grayscale version of the original image beneath the debug points
  • showimagecol=true: show a colour version of the original image beneath the debug points
triangulArt(bird, npts=500)

triangulArt(bird, npts=100, refine=true)

triangulArt(bird, npts=100, debug=true)

triangulArt(bird, npts=100, debug=true, showimage=false)

Method

Following the the original script described here, this package first generates points spaced evenly around the border.

Rather than randomly selecting points around the image, especially where there are large blocks of a single colour, points should be selected where large changes occur, e.g. from one colour to the another (an edge). I did attempt to solve this with an edge-detection algorithm, but even better is to use the local entropy of the image, determined as the number of bits required to encode the histogram of the grayscale pixes in that region.

The entropy of each point is calculated using a disk of 20px - this currently uses skimage directly from python as the closest Julia implementation I could find uses a square ImageFiltering::mapwindow(). Otherwise, a close equivalent would be

function shannon(w::AbstractMatrix)
    cm = collect(values(countmap(w))) / sum(size(w)) / 256
    sum([-x * log2(x) for x in cm])
end

# window dimensions must be odd
mapwindow(shannon, im1, (19, 19))

The point with the highest entropy is selected, then a Gaussian centered on this point is subtracted from the entropy, reducing the neighbouring points (so that the sampled points are not too close together).

These two steps - calculating the entropy and finding the point with the maximum entropy (currently via findmax()) are the two largest bottlenecks to performance.

Once npts are selected, a DelaunayTriangulation::triangulate() is performed on the combined edge points and maximum-entropy points. If requested, this is DelaunayTriangulation::refine()d.

The triangle to which each pixel belongs is calculated, then the average colour of each triangle is determined. The triangles are then drawn and filled with the respective average colour.

The source for the python version is forked here where I have made minor tweaks to bring it back up to date with current package versions.

Limitations / Known Issues

  • The white border around the produced image remains - I have tried setting margin=0mm but that doesn't appear to help

  • Performance is not as good as it can be, I suspect; the entropy calculation (calling python) is definitely a bottleneck. Profiling also suggests the findmax() is expensive.

  • To speed up the processing, only every 10th pixel is used to determine the average colour of the triangle - this may fail to identify an entire triangle.

  • CI - I generated this package in VSCode using PkgTemplates and it is the first Julia package I've built. CI failed immediately, so I've probably done something wrong.

  • I am still somewhat of a beginner in Julia, so there are probably many places in which improvements can be made - feel free to suggest them!

About

Artify images using Delaunay Triangulation

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Julia 100.0%