Twitter image encoding challenge

image files and python source (version 1 and 2)

Version 1 Here is my first attempt. I will update as I go.

I have got the SO logo down to 300 characters almost lossless. My technique uses conversion to SVG vector art so it works best on line art. It is actually an SVG compressor, it still requires the original art go through a vectorisation stage.

For my first attempt I used an online service for the PNG trace however there are MANY free and non-free tools that can handle this part including potrace (open-source).

Here are the results

Original SO Logo http://www.warriorhut.org/graphics/svg_to_unicode/so-logo.png Original Decoded SO Logo http://www.warriorhut.org/graphics/svg_to_unicode/so-logo-decoded.png After encoding and decoding

Characters: 300

Time: Not measured but practically instant (not including vectorisation/rasterisation steps)

The next stage will be to embed 4 symbols (SVG path points and commands) per unicode character. At the moment my python build does not have wide character support UCS4 which limits my resolution per character. I've also limited the maximum range to the lower end of the unicode reserved range 0xD800 however once I build a list of allowed characters and a filter to avoid them I can theoretically push the required number of characters as low as 70-100 for the logo above.

A limitation of this method at present is the output size is not fixed. It depends on number of vector nodes/points after vectorisation. Automating this limit will require either pixelating the image (which removes the main benefit of vectors) or repeated running the paths through a simplification stage until the desired node count is reached (which I'm currently doing manually in Inkscape).

Version 2

UPDATE: v2 is now qualified to compete. Changes:

  • Command-line control input/output and debugging
  • Uses XML parser (lxml) to handle SVG instead of regex
  • Packs 2 path segments per unicode symbol
  • Documentation and cleanup
  • Support style="fill:color" and fill="color"
  • Document width/height packed into single character
  • Path color packed into single character
  • Color compression is acheived by throwing away 4bits of color data per color then packing it into a character via hex conversion.

Characters: 133

Time: A few seconds

v2 decoded http://www.warriorhut.org/graphics/svg_to_unicode/so-logo-decoded-v2.png After encoding and decoding (version 2)

As you can see there are some artifacts this time. It isn't a limitation of the method but a mistake somewhere in my conversions. The artifacts happen when the points go outside the range 0.0 - 127.0 and my attempts to constrain them have had mixed success. The solution is simply to scale the image down however I had trouble scaling the actual points rather than the artboard or group matrix and I'm too tired now to care. In short, if your points are in the supported range it generally works.

I believe the kink in the middle is due to a handle moving to the other side of a handle it's linked to. Basically the points are too close together in the first place. Running a simplify filter over the source image in advance of compressing it should fix this and shave of some unnecessary characters.

UPDATE: This method is fine for simple objects so I needed a way to simplify complex paths and reduce noise. I used Inkscape for this task. I've had some luck with grooming out unnecessary paths using Inkscape but not had time to try automating it. I've made some sample svgs using the Inkscape 'Simplify' function to reduce the number of paths.

Simplify works ok but it can be slow with this many paths.

autotrace example http://www.warriorhut.org/graphics/svg_to_unicode/autotrace_16_color_manual_reduction.png cornell box http://www.warriorhut.com/graphics/svg_to_unicode/cornell_box_simplified.png lena http://www.warriorhut.com/graphics/svg_to_unicode/lena_std_washed_autotrace.png

thumbnails traced http://www.warriorhut.org/graphics/svg_to_unicode/competition_thumbnails_autotrace.png

Here's some ultra low-res shots. These would be closer to the 140 character limit though some clever path compression may be need as well.

groomed http://www.warriorhut.org/graphics/svg_to_unicode/competition_thumbnails_groomed.png Simplified and despeckled.

trianglulated http://www.warriorhut.org/graphics/svg_to_unicode/competition_thumbnails_triangulated.png Simplified, despeckled and triangulated.

autotrace --output-format svg --output-file cornell_box.svg --despeckle-level 20 --color-count 64 cornell_box.png

ABOVE: Simplified paths using autotrace.

Unfortunately my parser doesn't handle the autotrace output so I don't know how may points are in use or how far to simplify, sadly there's little time for writing it before the deadline. It's much easier to parse than the inkscape output though.


Alright, here's mine: nanocrunch.cpp and the CMakeLists.txt file to build it using CMake. It relies on the Magick++ ImageMagick API for most of its image handling. It also requires the GMP library for bignum arithmetic for its string encoding.

I based my solution off of fractal image compression, with a few unique twists. The basic idea is to take the image, scale down a copy to 50% and look for pieces in various orientations that look similar to non-overlapping blocks in the original image. It takes a very brute force approach to this search, but that just makes it easier to introduce my modifications.

The first modification is that instead of just looking at ninety degree rotations and flips, my program also considers 45 degree orientations. It's one more bit per block, but it helps the image quality immensely.

The other thing is that storing a contrast/brightness adjustment for each of color component of each block is way too expensive. Instead, I store a heavily quantized color (the palette has only 4 * 4 * 4 = 64 colors) that simply gets blended in in some proportion. Mathematically, this is equivalent to a variable brightness and constant contrast adjustment for each color. Unfortunately, it also means there's no negative contrast to flip the colors.

Once it's computed the position, orientation and color for each block, it encodes this into a UTF-8 string. First, it generates a very large bignum to represent the data in the block table and the image size. The approach to this is similar to Sam Hocevar's solution -- kind of a large number with a radix that varies by position.

Then it converts that into a base of whatever the size of the character set available is. By default, it makes full use of the assigned unicode character set, minus the less than, greater than, ampersand, control, combining, and surrogate and private characters. It's not pretty but it works. You can also comment out the default table and select printable 7-bit ASCII (again excluding <, >, and & characters) or CJK Unified Ideographs instead. The table of which character codes are available is stored a run-length encoded with alternating runs of invalid and valid characters.

Anyway, here are some images and times (as measured on my old 3.0GHz P4), and compressed to 140 characters in the full assigned unicode set described above. Overall, I'm fairly pleased with how they all turned out. If I had more time to work on this, I'd probably try to reduce the blockiness of the decompressed images. Still, I think the results are pretty good for the extreme compression ratio. The decompressed images are bit impressionistic, but I find it relatively easy to see how bits correspond to the original.

Stack Overflow Logo (8.6s to encode, 7.9s to decode, 485 bytes):
http://i44.tinypic.com/2w7lok1.png

Lena (32.8s to encode, 13.0s to decode, 477 bytes):
http://i42.tinypic.com/2rr49wg.png http://i40.tinypic.com/2rhxxyu.png

Mona Lisa (43.2s to encode, 14.5s to decode, 490 bytes):
http://i41.tinypic.com/ekgwp3.png http://i43.tinypic.com/ngsxep.png

Edit: CJK Unified Characters

Sam asked in the comments about using this with CJK. Here's a version of the Mona Lisa compressed to 139 characters from the CJK Unified character set:

http://i43.tinypic.com/2yxgdfk.png 咏璘驞凄脒鵚据蛥鸂拗朐朖辿韩瀦魷歪痫栘璯緍脲蕜抱揎頻蓼債鑡嗞靊寞柮嚛嚵籥聚隤慛絖銓馿渫櫰矍昀鰛掾撄粂敽牙稉擎蔍螎葙峬覧絀蹔抆惫冧笻哜搀澐芯譶辍澮垝黟偞媄童竽梀韠镰猳閺狌而羶喙伆杇婣唆鐤諽鷍鴞駫搶毤埙誖萜愿旖鞰萗勹鈱哳垬濅鬒秀瞛洆认気狋異闥籴珵仾氙熜謋繴茴晋髭杍嚖熥勳縿餅珝爸擸萿

The tuning parameters at the top of the program that I used for this were: 19, 19, 4, 4, 3, 10, 11, 1000, 1000. I also commented out the first definition of number_assigned and codes, and uncommented out the last definitions of them to select the CJK Unified character set.