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The closest contenders that I could find so far are yEnc (2%) and ASCII85 (25% overhead). There seem to be some issues around yEnc mainly around the fact that it uses an 8-bit character set. Which leads to another thought: is there a binary to text encoding based on the UTF-8 character set?

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This really depends on the nature of the binary data, and the constraints that "text" places on your output.

First off, if your binary data is not compressed, try compressing before encoding. We can then assume that the distribution of 1/0 or individual bytes is more or less random.

Now: why do you need text? Typically, it's because the communication channel does not pass through all characters equally. e.g. you may require pure ASCII text, whose printable characters range from 0x20-0x7E. You have 95 characters to play with. Each character can theoretically encode log2(95) ~= 6.57 bits per character. It's easy to define a transform that comes pretty close.

But: what if you need a separator character? Now you only have 94 characters, etc. So the choice of an encoding really depends on your requirements.

To take an extremely stupid example: if your channel passes all 256 characters without issues, and you don't need any separators, then you can write a trivial transform that achieves 100% efficiency. :-) How to do so is left as an exercise for the reader.

UTF-8 is not a good transport for arbitrarily encoded binary data. It is able to transport values 0x01-0x7F with only 14% overhead. I'm not sure if 0x00 is legal; likely not. But anything above 0x80 expands to multiple bytes in UTF-8. I'd treat UTF-8 as a constrained channel that passes 0x01-0x7F, or 126 unique characters. If you don't need delimeters then you can transmit 6.98 bits per character.

A general solution to this problem: assume an alphabet of N characters whose binary encodings are 0 to N-1. (If the encodings are not as assumed, then use a lookup table to translate between our intermediate 0..N-1 representation and what you actually send and receive.)

Assume 95 characters in the alphabet. Now: some of these symbols will represent 6 bits, and some will represent 7 bits. If we have A 6-bit symbols and B 7-bit symbols, then:

A+B=95 (total number of symbols) 2A+B=128 (total number of 7-bit prefixes that can be made. You can start 2 prefixes with a 6-bit symbol, or one with a 7-bit symbol.)

Solving the system, you get: A=33, B=62. You now build a table of symbols:

Raw     Encoded
000000  0000000
000001  0000001
100000  0100000
1000010 0100001
1000011 0100010
1111110 1011101
1111111 1011110

To encode, first shift off 6 bits of input. If those six bits are greater or equal to 100001 then shift another bit. Then look up the corresponding 7-bit output code, translate to fit in the output space and send. You will be shifting 6 or 7 bits of input each iteration.

To decode, accept a byte and translate to raw output code. If the raw code is less than 0100001 then shift the corresponding 6 bits onto your output. Otherwise shift the corresponding 7 bits onto your output. You will be generating 6-7 bits of output each iteration.

For uniformly distributed data I think this is optimal. If you know that you have more zeros than ones in your source, then you might want to map the 7-bit codes to the start of the space so that it is more likely that you can use a 7-bit code.

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The short answer would be: No, there still isn't.

I ran into the problem with encoding as much information into JSON string, meaning UTF-8 without control characters, backslash and quotes.

I went out and researched how many bit you can squeeze into valid UTF-8 bytes. I disagree with answers stating that UTF-8 brings too much overhead. It's not true.

If you take into account only one-byte sequences, it's as powerful as standard ASCII. Meaning 7 bits per byte. But if you cut out all special characters you'll be left with something like Ascii85.

But there are fewer control characters in higher planes. So if you use 6-byte chunks you'll be able to encode 5 bytes per chunk. In the output you'll get any combination of UTF-8 characters of any length (for 1 to 6 bytes).

This will give you a better result than Ascii85: 5/6 instead of 4/5, 83% efficiency instead of 80%. In theory it'll get even better with higher chunk length: about 84% at 19-byte chunks.

In my opinion the encoding process becomes too complicated while it provides very little profit. So Ascii85 or some modified version of it (I'm looking at Z85 now) would be better.

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I searched for most efficient binary to text encoding last year. I realized for myself that compactness is not the only criteria. The most important is where you are able to use encoded string. For example, yEnc has 2% overhead, but it is 8-bit encoding, so its usage is very very limited.

My choice is Z85. It has acceptable 25% overhead, and encoded string can be used almost everywhere: XML, JSON, source code etc. See Z85 specification for details.

Finally, I've written Z85 library in C/C++ and use it in production.

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According to Wikipedia "basE91 produces the shortest plain ASCII output for compressed 8-bit binary input."

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Sounds like you already have the answer, Mark. UTF-8 is not useful as a Binary encoding since any UTF-8 character larger than one byte has over 25% overhead even to store text (2 or more bits per byte). Base64 encodings are already better than that.

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Base 64 encoding is compatible with ASCII, and since UTF-8 maps to ASCII for any character under 7F hex, UTF-8 has at least the same density as base 64. That said, for really dense encodings, 8 bit encodings such as Windows-1252 may be a better idea. – Maarten Bodewes Dec 17 '12 at 22:00

Next to the ones listed on Wikipedia, there is Bommanews:

B-News (or bommanews) was developed to lift the weight of the overhead inherent to UUEncode and Base64 encoding: it uses a new encoding method to stuff binary data in text messages. This method eats more CPU resources, but it manages to lower the loss from approximately 40% for UUEncode to 3.5% (the decimal point between those digits is not dirt on your monitor), while still avoiding the use of ANSI control codes in the message body.

It's comparable to yEnc: source

yEnc is less CPU-intensive than B-News and reaches about the same low level of overhead, but it doesn't avoid the use of all control codes, it just leaves out those that were (experimentally) observed to have undesired effects on some servers, which means that it's somewhat less RFC compliant than B-News.

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The FAQ of Bommanews does not go into which character-encoding's are supported. I presume most 8 bit code pages, although 7F may be present, and that's a control code in e.g. in the IBM OEM character set. Even in the Windows code pages 81, 8D, 8F, 90, and 9D are control characters. Beware when printing this stuf, because data will be lost. – Maarten Bodewes Dec 17 '12 at 21:55

For inspiration, you might want to check the Twitter Image Encoding Challenge out. It's about encoding as much image information as possible in 140 Unicode characters. It's essentially a lossy version of your question specifically tied to image data.

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