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I have a password generator:

import random, string

def gen_pass():
    foo = random.SystemRandom()
    length = 64
    chars = string.letters + string.digits
    return ''.join(foo.choice(chars) for _ in xrange(length))

According to the docs, SystemRandom uses os.urandom which uses /dev/urandom to throw out random cryto bits. In Linux you can get random bits from /dev/urandom or /dev/random, they both use whatever entropy the kernel can get its hands on. The amount of entropy available can be checked with tail /proc/sys/kernel/random/entropy_avail, this will return a number like: 129. The higher the number more entropy is available. The difference between /dev/urandom and /dev/random is that /dev/random will only spit out bits if entropy_avail is high enough (like at least 60) and /dev/urandom will always spit out bits. The docs say that /dev/urandom is good for crypto and you only have to use /dev/random for ssl certs and the like.

My question is will gen_pass be good for making strong crypto grade passwords always? If I call this function as quickly as possible will I stop getting strong cryto bits at some point because the entropy pool is depleted?

The question could also be why does /dev/urandom always produce strong cryto bits and not care about the entropy_avail?

It is possible that /dev/urandom is designed so that its bandwidth is capped by the number of cycles you can guess will be correlated with an amount of entropy, but this is speculation and I can't find an answer.

Also this is my first stackoverflow question so please critique me. I am concerned that I gave to much background when someone who knows the answer probably knows the background.



I wrote some code to look at the entropy pool while the /dev/urandom was being read from:

import subprocess
import time

from pygooglechart import Chart
from pygooglechart import SimpleLineChart
from pygooglechart import Axis

def check_entropy():
    arg = ['cat', '/proc/sys/kernel/random/entropy_avail']
    ps = subprocess.Popen(arg,stdout=subprocess.PIPE)
    return int(ps.communicate()[0])

def run(number_of_tests,resolution,entropy = []):
    i = 0
    while i < number_of_tests:        
        entropy += [check_entropy()]
        i += 1

def graph(entropy,rng):    
    max_y = 200    
    chart = SimpleLineChart(600, 375, y_range=[0, max_y])
    left_axis = range(0, max_y + 1, 32)
    left_axis[0] = 'entropy'
    chart.set_axis_labels(Axis.LEFT, left_axis)    
    chart.set_axis_labels(Axis.BOTTOM,['time in second']+get_x_axis(rng))'line-stripes.png')

def get_x_axis(rng):
    global modnum        
    if len(filter(lambda x:x%modnum == 0,range(rng + 1)[1:])) > 10:
        modnum += 1
        return get_x_axis(rng)
    return filter(lambda x:x%modnum == 0,range(rng + 1)[1:])

modnum = 1

If run this and also run:

while 1 > 0:

Then I pretty reliablly get a graph that looks like this: enter image description here

Making the graph while running cat /dev/urandom looks smiler and cat /dev/random drops off to nothing and stays low very quickly (this also only reads out like a byte every 3 seconds or so)


If I run the same test but with six instances of gen_pass(), I get this: enter image description here

So it looks like something is making it be the case that I have enough entropy. I should measure the password generation rate and make sure that it is actually being capped, because if it is not then something fishy may be going on.


I found this email chain

This says that urandom will stop pulling entropy once the pool only has 128 bits in it. This is very consistent with the above results and means that in those tests I am producing junk passwords often.

My assumption before was that if the entropy_avail was high enough (say above 64 bits) then /dev/urnadom output was good. This is not the case it seems that /dev/urandom was designed to leave extra entropy for /dev/random in case it needs it.

Now I need to find out how many true random bits a SystemRandom call needs.

share|improve this question
Naturally it's possible - you can draw an indefinite amount of information from /dev/urandom, and you don't have an indefinite amount of entropy. – Nick Johnson Mar 30 '11 at 23:57
Like I said above, I think you could design is so that it is not possible, but I have no reason the believe this. I need to do more research. – Chris Mar 31 '11 at 0:20
@Chris How? The entropy has to come from somewhere - you can't just magic it up. If you could, our lives would be a lot easier. – Nick Johnson Mar 31 '11 at 0:21
If you assume a average rate of entropy generation, and then you force the /dev/urandom process to take a certain amount of time (say by doing a bunch of hashes) then you could more or less force it to be the case that there is enough entropy by computationally limiting the bandwidth of reading out /dev/urandom. This requires the kernel being aware how quickly it generally generated entropy and throttling the bandwidth dynamically, or using some lower bound assumption for entropy generation. – Chris Mar 31 '11 at 6:28
@Chris The point of urandom is to return as much data as is needed - /dev/random exists if you need guaranteed entropy. – Nick Johnson Mar 31 '11 at 12:00
up vote 6 down vote accepted

There's a subtle difference between the output of /dev/random and /dev/urandom. As has been pointed out, /dev/urandom doesn't block. That's because it gets its output from a pseudo-random number generator, seeded from the 'real' random numbers in /dev/random.

The output of /dev/urandom will almost always be sufficiently random -- it's a high-quality PRNG with a random seed. If you really need a better source of random data, you could consider getting a system with a hardware random number generator -- my netbook has a VIA C7 in it, which can generate quite a lot of properly random data (I get a consistent 99.9kb/s out of /dev/random, 545kb/s out of /dev/urandom).

As an aside, if you're generating passwords then you might want to look at pwgen -- it makes nice pronounceable passwords for you :).

share|improve this answer
Rite, I think I've proven to myself that this will work well, but to be safe hardware is the way to go. Now I just need to figure out how to hook my geiger counter up to a serial port... – Chris Apr 1 '11 at 5:02

/dev/random/ will block on read if it needs more entropy. /dev/urandom/ won't. So yes, if you use it too fast you'll run low on entropy. Probably still quite hard to guess, of course, but if you're really concerned you can read bytes from /dev/random/ instead. Ideally, with a non-blocking read loop and a progress indicator so you can move the mouse around and generate entropy if needed.

share|improve this answer
/dev/random actually seems to give you the bits directly from the entropy pool, and from the experiments the entropy is depleted very quickly. If it is possible for /dev/urandom to fail I would like to know more about how it does and if you can prevent it. If you run cat /dev/urandom and spew crap to standard IO and also check the entropy_avail periodically there does not seem to be a problem with the entropy_avail ever. It makes me wonder if the kernel is using the process of printing /dev/urandom/ to make more entropy, I also wonder if that is acceptable. – Chris Mar 30 '11 at 3:43
My recollection is that they take it from the same place, but random keeps track of how much entropy is available and blocks when it needs more. I would suppose that urandom also updates the entropy status, since someone might draw on random at any time. How are you checking entropy_avail? Anyway, I'd say using urandom and passing it through a secure hash function would be secure enough for almost any application. – Tom Zych Mar 30 '11 at 13:20

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