Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have an embedded system. What I would like for it to do when it powers up or otherwise resets, is to generate a unique ID, so that on different restarts a different unique ID is generated with high probability.

It does not have access to a real-time clock, but it does have access to an ADC and a UART. I am wondering if there is a decent way to gather entropy from these sources to generate a unique ID. I am vaguely familiar with Yarrow. Is there a good way to use this?

Unfortunately I do not have any noise sources of predictable characteristics; the ADC is connected to a number of relatively-low-noise inputs, so I suppose I could just use the least-significant bits of the ADC as inputs.

edit: for what it's worth, this is the TI TMS320F28335 processor.


update/clarification: I was looking for a method in software of gathering entropy. I found another way to solve my problem, so in a way, my question was a moot point, but I am still looking for guidance on specific software solutions to gather entropy from low-entropy sources like least-significant bits of the ADC and system timing for receiving UART characters.

share|improve this question
    
what processor? There might be some chip specific options... –  dls Sep 22 '10 at 1:54
    
Can you add custom hardware to the ADC port? If so you can append a zener diode noise generator there. electronicdesign.com/article/test-and-measurement/… –  Rudi Sep 23 '10 at 14:08
    
nope, the hardware is fixed. You're talking about high-quality hardware noise sources and I don't have any. –  Jason S Sep 23 '10 at 14:32

5 Answers 5

up vote 10 down vote accepted

I've used:

  • the lowest bit of a floating ADC input, but you touched on that

  • an extremely high-resolution timer (~10ns), and taken the lowest "n" bits when timing between user keypresses. If you accept that user keypresses (at the highest timing resolution) are effectively random in their timing, it works pretty well.

You could also time things like time between network packets, etc. but those can be a lot more deterministic/predictable than what a lot of people thing. Electrical noise and user interaction are better sources of entropy.

By the way, on the "timings between keypresses" stuff, I tend to store those on an embedded system starting at power-on, in a circular buffer of the last 8 or so, because you never know when you're going to need them. (IN other words: Don't wait until you need the random bits, and then force the user to press buttons 3 times!)

share|improve this answer

See also Fortuna, described in Practical Cryptography by Niels Ferguson and Bruce Schneier. Although, both Yarrow and Fortuna might be too heavy-weight for an embedded system.

Unlike Yarrow, Fortuna doesn't require you to estimate the entropy of your random sources.

share|improve this answer

I have done something similar to Dan's answer. I had a buffer in non volatile memory with the timer difference using a high resolution timer (20ns) between user keystrokes containing the last 256 keystrokes times. I then compute a 32 bit CRC to get a unique number each time the system is power on. Some versions without user interaction measured the time between message received on the serial ports

These unique numbers was used as node identifiers on a network and there has never been any problems with duplicates.

This was later augmented with a DS2401 that provided a persistent but unique ID but this would only work for you if you can change the hardware.

share|improve this answer

It depends:

  • What degree of uniqueness do you want?
  • Is there any non-volatile storage?
  • How soon do you need an answer?

If you have flash/NVRAM/disk, read your random seed, increment it, and write it back. The seed can be a simple counter if you don't require uniqueness between devices/reflashing/NVRAM battery running out. If you want uniqueness, then once you've gathered "enough" entropy, rewrite the seed.

(Obviously you might want to do something else if you're using flash and your flash controller doesn't have wear-levelling, or implement your own wear-levelling.)

If you don't, then collect entropy from all the sources you can, and only generate the UUID after you have enough entropy. Zvi Gutterman (2006) notes that OpenWRT's only source of entropy is network access, which is easily observed.

Using ADC output seems sensible, with some simple guidelines:

  • Use all the bits (or at least more bits than your entropy estimate), but increase your entropy estimate conservatively.
  • ADC output has zero entropy when clipped (and possibly low entopy when nearly clipped).

Measure the amount of noise on the input. I suspect you'll get at least one bit per sample. Then hash your bits and generate a version 4 UUID.

share|improve this answer

Minor addition to Dan's answer above... If your system includes some sort of radio you can take an RSSI reading.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.