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(I know many people are going to be tempted to close this question; please don't; I'm asking for concrete technical answers, if any exist.)

"Network byte order" is big-endian for reasons that cannot be asked on stackoverflow. Lots of old protocols use that order and can't be changed but I wonder if there are any technical reasons to choose big endian for a new protocol.

I would think little endian is better, because 99.99% of processors in use are little endian (ARM can technically do both, but in reality it is always set to little endian). So I was surprised to see that CBOR, a relatively recent protocol, uses big endian. Is there an advantage that I haven't thought of?

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It boils down to human factors: It is easier to read a multi-byte integer in a hex dump if it is encoded with the most significant byte(s) first. For example, the CBOR representation of 0x1234 (4,660) is the byte sequence 19 12 34. If you are looking for the value 0x1234, it is easier to spot it that way.

TLDR;

I've been in the field for over 40 years now, so there's a lot of history behind this. Even the definition of a "byte" has changed over that many years, so this may take a bit of an open mind to understand how this evolved.

Dumps of binary information weren't always in bytes, nor hexadecimal. For example, the PDP-10 machine architecture (big in the early days of the internet), used a 36 bit word. Since 36 bits is not evenly dividable by 4 bits, but it is divisible by 3 bits, octal octal (base 8 notation) was typically used for dumping the contents of memory to a printer.

Even the PDP-11 (with 16-bit words, and 8-bit bytes) the use of octal notation word-wide dumps was common. With other computer architectures however the usefulness of octal declined, and hex dumps became common, but even then dumping words (16 or 32 bit) rather than byte at a time was commonly required for little-endinan machines, while a big-endian machine could just dump bytes and let the human group them together (without byte swapping) visually.

  • I don't think people using CBOR (or any other binary protocol) generally decode it by reading raw hex though, so that doesn't seem like a very good reason to require practically every computer in the world to do two pointless endianness swaps. – Timmmm Apr 30 '18 at 2:26
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    You miss my point. You asked if there were any technical reasons to choose big endian for a new protocol. I'm saying yes, but it doesn't have to do with how protocol decoders operate, it has to do with human factors. This sort of human factor is still quite technical and relates to human activities needed while adopting new protocols. – Burt_Harris May 1 '18 at 23:41
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    Perhaps you assume that the byte swapping causes a performance hit. That used to bother me too, but as processors have gotten faster, it bothers me less and less. At this point, I would be surprised if you could meaningfullly measure any significant application-level performance difference if CBOR were little-endian instead of big-endian. Generally the speed of gettings bytes in/out of a system will dominate practical performance, not internal processor-level work like byte swapping. – Burt_Harris May 1 '18 at 23:52

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