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I'm interested in creating a very simple, high (cryptographic) quality random password generator. Is there a better way to do this?

import os, random, string

length = 13
chars = string.ascii_letters + string.digits + '!@#$%^&*()'
random.seed = (os.urandom(1024))

print ''.join(random.choice(chars) for i in range(length))
share|improve this question
3  
Are these passwords for humans or machines? –  cheeken Sep 20 '11 at 2:36
3  
randomness != cryptography –  Jarrod Roberson Sep 20 '11 at 3:00
11  
@JarrodRoberson Stating that “randomness != cryptography” is just egregious in and of itself, since modern cryptography is built on randomness. Not all randomness is created equal (eg: a password selected at random from “password” and “passwords” is obviously not secure), but at its heart, cryptography == randomness. –  NullUserException Sep 20 '11 at 14:30
2  
Isn't random.seed a method, so random.seed = 'random_string' basically destroys that method and doesn't do anything? Do you mean random.seed('random_string')? –  Nick T Nov 4 '13 at 22:24
1  
os.urandom(1024) fetches 1024 bytes. It seems a bit excessive to me. Perhaps seeding with 16 or 32 bytes would be more appropriate. –  jww Jun 6 at 22:23

13 Answers 13

The difficult thing with passwords is to make them strong enough and still be able to remember them. If the password is not meant to be remembered by a human being, then it is not really a password.

You use Python's os.urandom(): that's good. For any practical purpose (even cryptography), the output of os.urandom() is indistinguishable from true alea. Then you use it as seed in random, which is less good: that one is a non-cryptographic PRNG, and its output may exhibit some structure which will not register in a statistical measurement tool, but might be exploited by an intelligent attacker. You should work with os.urandom() all along. To make things simple: choose an alphabet of length 64, e.g. letters (uppercase and lowercase), digits, and two extra punctuation characters (such as '+' and '/'). Then, for each password character, get one byte from os.urandom(), reduce the value modulo 64 (this is unbiased because 64 divides 256) and use the result as index in your chars array.

With an alphabet of length 64, you get 6 bits of entropy per character (because 26 = 64). Thus, with 13 characters, you get 78 bits of entropy. This is not ultimately strong in all cases, but already very strong (it could be defeated with a budget which will be counted in months and billions of dollars, not mere millions).

share|improve this answer
    
Waaait a minute... This might sound like a dumb question, but os.urandom() returns type bytes, so how can I reduce that mod 64? –  Sean Aug 26 at 17:06
    
Ask for one byte, then get the byte value, which is an integer in the 0 to 255 range. –  Thomas Pornin Aug 26 at 18:36
    
But it's pretty hard to remember 13 random characters. That is actually Randall's point in the famous XKCD comic. I'd suggest github.com/redacted/XKCD-password-generator using its --acrostic option to get a pattern you find even easier to remember. –  nealmcb Sep 7 at 3:56

XKCD has a great explanation of why what you think are strong passwords aren't.

http://xkcd.com/936/

To anyone who understands information theory and security and is in an infuriating argument with someone who does not (possibly involving mixed case), I sincerely apologize. - Randall Munroe

And if you don't understand the math behind what this illustration is explaining, don't try writing anything that should be cryptographically secure, because it won't be. Just put the mouse down and step away from the keyboard.

share|improve this answer
15  
Second, it seems like you are the one who doesn’t understand the concepts behind the illustration. A randomly generated 13-character password generated from 72 characters has log(72^13)/log(2) = 80 bits of entropy. Granted, it will be extremely hard to remember, but that’s more than 44 bits of entropy (which I assume is calculated from 4 words drawn from ~2000 words = log(2000^4)/log(2)). The point Randall is trying to make is, the first password has much lower entropy because it is derived from a dictionary word with common substitutions. –  NullUserException Sep 20 '11 at 14:26
6  
@NullUserExceptionఠ_ఠ, I don't see a huge problem with the last statement, implementing cryptography without understanding it is a recipe for disaster. (Of course, the author of this post is the category of people who don't understand and thinks they do.) –  Winston Ewert Sep 20 '11 at 14:43
4  
There are two real points in the XKCD comic. First, that what you think of as having a lot of randomness may not actually have a lot of randomness. Second, that just because a password is cryptographically strong doesn't make it good -- a good password is easy to remember. Both of those points are valid, even if the opening statement of the answer is incorrect. I also disagree that the closing statement is either inflammatory or unnecessary. –  agf Sep 20 '11 at 15:16
7  
Lets keep comments constructive, please. –  Tim Post Sep 21 '11 at 3:43
5  
The first sentence is wrong: randomness does make "cryptographically strong" passwords, and the comic is pointedly contrasting a non-random, difficult password with a random, easy pass phrase. Entropy of English words is a function of dictionary size, not word length. Rather than 4.7 bits per letter, is more like 17 bits per word. It is easier for me to create a mnemonic for a sequence of medium-length root words, so suppose I create a dictionary of 2048 such words. Even if an attacker steals my list, each randomly chosen word still adds at least 11 bits of entropy to the pass phrase. –  erickson Sep 21 '11 at 16:43

Just two days ago, Kragen Javier Sitaker posted a program to do this at http://lists.canonical.org/pipermail/kragen-hacks/2011-September/000527.html (gone now - try https://github.com/jesterpm/bin/blob/master/mkpasswd)

Generate a random, memorizable password: http://xkcd.com/936/

Example run:

kragen at inexorable:~/devel/inexorable-misc$ ./mkpass.py 5 12 Your password is "learned damage saved residential stages". That's equivalent to a 60-bit key.

That password would take 2.5e+03 CPU-years to crack on my inexpensive Celeron E1200 from 2008, assuming an offline attack on a MS-Cache hash, which is the worst password hashing algorithm in common use, slightly worse than even simple MD5.

The most common password-hashing algorithm these days is FreeBSD’s iterated MD5; cracking such a hash would take 5.2e+06 CPU-years.

But a modern GPU can crack about 250 times as fast, so that same iterated MD5 would fall in 2e+04 GPU-years.

That GPU costs about US$1.45 per day to run in 2011, so cracking the password would cost about US$3e+09.

I've started using a password generated this way in place of a 9-printable- ASCII-character random password, which is equally strong. Munroe's assertion that these passwords are much easier to memorize is correct. However, there is still a problem: because there are many fewer bits of entropy per character (about 1.7 instead of 6.6) there is a lot of redundancy in the password, and so attacks such as the ssh timing-channel attack (the Song, Wagner, and Tian Herbivore attack, which I learned about from Bram Cohen in the Bagdad Café in the wee hours one morning, years ago) and keyboard audio recording attacks have a much better chance of capturing enough information to make the password attackable.

My countermeasure to the Herbivore attack, which works well with 9-character password but is extremely annoying with my new password, is to type the password with a half-second delay between characters, so that the timing channel does not carry much information about the actual characters used. Additionally, the lower length of the 9-character password inherently gives the Herbivore approach much less information to chew on.

Other possible countermeasures include using Emacs shell-mode, which prompts you locally for the password when it recognizes a password prompt and then sends the whole password at once, and copying and pasting the password from somewhere else.

As you'd expect, this password also takes a little while longer to type: about 6 seconds instead of about 3 seconds.

#!/usr/bin/python
# -*- coding: utf-8 -*-

import random, itertools, os, sys

def main(argv):
    try:
        nwords = int(argv[1])
    except IndexError:
        return usage(argv[0])

    try:
        nbits = int(argv[2])
    except IndexError:
        nbits = 11

    filename = os.path.join(os.environ['HOME'], 'devel', 'wordlist')
    wordlist = read_file(filename, nbits)
    if len(wordlist) != 2**nbits:
        sys.stderr.write("%r contains only %d words, not %d.\n" %
                         (filename, len(wordlist), 2**nbits))
        return 2

    display_password(generate_password(nwords, wordlist), nwords, nbits)
    return 0

def usage(argv0):
    p = sys.stderr.write
    p("Usage: %s nwords [nbits]\n" % argv0)
    p("Generates a password of nwords words, each with nbits bits\n")
    p("of entropy, choosing words from the first entries in\n")
    p("$HOME/devel/wordlist, which should be in the same format as\n")
    p("<http://canonical.org/~kragen/sw/wordlist>, which is a text file\n")
    p("with one word per line, preceded by its frequency, most frequent\n")
    p("words first.\n")
    p("\nRecommended:\n")
    p("    %s 5 12\n" % argv0)
    p("    %s 6\n" % argv0)
    return 1

def read_file(filename, nbits):
    return [line.split()[1] for line in
            itertools.islice(open(filename), 2**nbits)]

def generate_password(nwords, wordlist):
    choice = random.SystemRandom().choice
    return ' '.join(choice(wordlist) for ii in range(nwords))

def display_password(password, nwords, nbits):
    print 'Your password is "%s".' % password
    entropy = nwords * nbits
    print "That's equivalent to a %d-bit key." % entropy
    print

    # My Celeron E1200
    # (<http://ark.intel.com/products/34440/Intel-Celeron-Processor-E1200-(512K-Cache-1_60-GHz-800-MHz-FSB)>)
    # was released on January 20, 2008.  Running it in 32-bit mode,
    # john --test (<http://www.openwall.com/john/>) reports that it
    # can do 7303000 MD5 operations per second, but I’m pretty sure
    # that’s a single-core number (I don’t think John is
    # multithreaded) on a dual-core processor.
    t = years(entropy, 7303000 * 2)
    print "That password would take %.2g CPU-years to crack" % t
    print "on my inexpensive Celeron E1200 from 2008,"
    print "assuming an offline attack on a MS-Cache hash,"
    print "which is the worst password hashing algorithm in common use,"
    print "slightly worse than even simple MD5."
    print

    t = years(entropy, 3539 * 2)
    print "The most common password-hashing algorithm these days is FreeBSD’s"
    print "iterated MD5; cracking such a hash would take %.2g CPU-years." % t
    print

    # (As it happens, my own machines use Drepper’s SHA-2-based
    # hashing algorithm that was developed to replace the one
    # mentioned above; I am assuming that it’s at least as slow as the
    # MD5-crypt.)

    # <https://en.bitcoin.it/wiki/Mining_hardware_comparison> says a
    # Core 2 Duo U7600 can do 1.1 Mhash/s (of Bitcoin) at a 1.2GHz
    # clock with one thread.  The Celeron in my machine that I
    # benchmarked is basically a Core 2 Duo with a smaller cache, so
    # I’m going to assume that it could probably do about 1.5Mhash/s.
    # All common password-hashing algorithms (the ones mentioned
    # above, the others implemented in John, and bcrypt, but not
    # scrypt) use very little memory and, I believe, should scale on
    # GPUs comparably to the SHA-256 used in Bitcoin.

    # The same mining-hardware comparison says a Radeon 5870 card can
    # do 393.46 Mhash/s for US$350.

    print "But a modern GPU can crack about 250 times as fast,"
    print "so that same iterated MD5 would fall in %.1g GPU-years." % (t / 250)
    print

    # Suppose we depreciate the video card by Moore’s law,
    # i.e. halving in value every 18 months.  That's a loss of about
    # 0.13% in value every day; at US$350, that’s about 44¢ per day,
    # or US$160 per GPU-year.  If someone wanted your password as
    # quickly as possible, they could distribute the cracking job
    # across a network of millions of these cards.  The cards
    # additionally use about 200 watts of power, which at 16¢/kWh
    # works out to 77¢ per day.  If we assume an additional 20%
    # overhead, that’s US$1.45/day or US$529/GPU-year.
    cost_per_day = 1.45
    cost_per_crack = cost_per_day * 365 * t
    print "That GPU costs about US$%.2f per day to run in 2011," % cost_per_day
    print "so cracking the password would cost about US$%.1g." % cost_per_crack

def years(entropy, crypts_per_second):
    return float(2**entropy) / crypts_per_second / 86400 / 365.2422

if __name__ == '__main__':
    sys.exit(main(sys.argv))
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implementing @Thomas Pornin solution

import M2Crypto
import string

def random_password(length=10):
    chars = string.ascii_uppercase + string.digits + string.ascii_lowercase
    password = ''
    for i in range(length):
        password += chars[ord(M2Crypto.m2.rand_bytes(1)) % len(chars)]
    return password
share|improve this answer
1  
you could simply use os.urandom(1) (cryptographically strong) and remove the dependency from M2Crypto –  Riccardo Galli May 13 at 22:23

A simple implementation:

#!/usr/bin/env python

import string
from time import time
from itertools import chain
from random import seed, choice, sample


def mkpasswd(length=8, digits=2, upper=2, lower=2):
    """Create a random password

    Create a random password with the specified length and no. of
    digit, upper and lower case letters.

    :param length: Maximum no. of characters in the password
    :type length: int

    :param digits: Minimum no. of digits in the password
    :type digits: int

    :param upper: Minimum no. of upper case letters in the password
    :type upper: int

    :param lower: Minimum no. of lower case letters in the password
    :type lower: int

    :returns: A random password with the above constaints
    :rtype: str
    """

    seed(time())

    lowercase = string.lowercase.translate(None, "o")
    uppercase = string.uppercase.translate(None, "O")
    letters = "{0:s}{1:s}".format(lowercase, uppercase)

    password = list(
        chain(
            (choice(uppercase) for _ in range(upper)),
            (choice(lowercase) for _ in range(lower)),
            (choice(string.digits) for _ in range(digits)),
            (choice(letters) for _ in range((length - digits - upper - lower)))
        )
    )

    return "".join(sample(password, len(password)))
share|improve this answer

Another implemention of the XKCD method:

#!/usr/bin/env python
import random
import re

# apt-get install wbritish
def randomWords(num, dictionary="/usr/share/dict/british-english"):
  r = random.SystemRandom() # i.e. preferably not pseudo-random
  f = open(dictionary, "r")
  count = 0
  chosen = []
  for i in range(num):
    chosen.append("")
  prog = re.compile("^[a-z]{5,9}$") # reasonable length, no proper nouns
  if(f):
    for word in f:
      if(prog.match(word)):
        for i in range(num): # generate all words in one pass thru file
          if(r.randint(0,count) == 0): 
            chosen[i] = word.strip()
        count += 1
  return(chosen)

def genPassword(num=4):
  return(" ".join(randomWords(num)))

if(__name__ == "__main__"):
  print genPassword()

Sample output:

$ ./randompassword.py
affluent afford scarlets twines
$ ./randompassword.py
speedboat ellipse further staffer
share|improve this answer

Considering your comment,

I just need to be able to generate passwords that are more secure than the ones I would come up with in my head.

it seems you want to use your program to generate passwords, rather than just writing it as an exercise. It is preferable to use an existing implementation, because if you make a mistake, the output might be compromised. Read about random number generator attacks; in particular, a well-known RNG bug in Debian exposed people's SSL private keys.

So instead, consider using pwgen. It provides several options, which you should choose depending on what you plan to use the passwords for.

share|improve this answer
1  
The Debian vulnerability was an implementation error. Generally, /dev/urando & /dev/random are non-distinguishable from true random (except for the first 10 minutes or so after system boot) –  Jacco Sep 20 '11 at 7:39

That way works. It is perfectly fine. If you had additional rules, such as excluding dictionary words, then you may want to include those filters as well, but the likelihood of randomly generating a dictionary word with that setup is extremely small.

share|improve this answer

I know this question was posted back in 2011, but for those coming to it now in 2014 and beyond, I have one thing to say: RESIST THE URGE TO REINVENT THE WHEEL.

In my opinion, in these situations the best bet is to do a search for open-source software, e.g., constrain your results to github results. By far the best thing I've found:

https://github.com/redacted/XKCD-password-generator

share|improve this answer
    
Agreed. There are some nice options in the github version, e.g. to print out how much entropy your password has, and to let you provide an "acrostic" so that the first character of each word matches a word of your choice. –  nealmcb Sep 7 at 3:00

Implenting @Thomas Pornin solution: (can't comment @Yossi inexact answer)

import string, os
chars = string.letters + string.digits + '+/'
assert 256 % len(chars) == 0  # non-biased later modulo
PWD_LEN = 16
print ''.join(chars[ord(c) % len(chars)] for c in os.urandom(PWD_LEN))
share|improve this answer

You can't trust python's pseudo random number generator when generating a password. It is not necessarily cryptographically random. You are seeding the pseudo random number generator from os.urandom which is a good start. But then you depend on python's generator after that.

A better choice would be the random.SystemRandom() class which takes random numbers from the same source as urandom. According to the python documentation that should be good enough for cryptographic use. The SystemRandom class gives you everything that the main random class does but you don't need to worry about the pseudorandomness.

Example code using random.SystemRandom (for Python 2.6):

import os, random, string
length = 13
chars = string.ascii_letters + string.digits + '!@#$%^&*()'

rnd = random.SystemRandom()
print ''.join(rnd.choice(chars) for i in range(length))

Note: Your mileage may vary - the Python Documentation says that random.SystemRandom availability varies by operating system.

share|improve this answer
    
The Linux PRNG (/dev/urandom) is considered cryptographically secure. See security.stackexchange.com/questions/3936/…. –  Mechanical snail Sep 20 '11 at 4:04
4  
I think you are getting your concepts mixed up here. In a deterministic computer there is no true randomness; everything (including /dev/urandom) is pseudo random unless you have specialized hardware. –  NullUserException Sep 20 '11 at 4:11
    
@NullUserExceptionఠ_ఠ +1 A consumer can do this with a webcam or CCD in a pitch black environment (see LavaRnd). –  darvids0n Sep 20 '11 at 4:46
    
@NullUserExceptionఠ_ఠ, There a few source of randomness that your computer does collect. However, I was wrong, urandom mixes that with a pseudorandom number generator. Nevertheless, using SystemRandom is a good idea because you can be sure its cryptographically random whereas the same isn't neccesairly true of the python random number generator. –  Winston Ewert Sep 20 '11 at 12:15

Here is another implementation (python 2; would require some minor rewrites to get it working in 3) that is much faster than OJW's, which seems to loop through the dictionary for each word, despite the comment/implication to the contrary. Timing of OJW's script on my machine, with an 80,000 IOP SSD:

real    0m3.264s
user    0m1.768s
sys     0m1.444s

The following script loads the whole dictionary into a list, then picks words based on a random selection of the index value, using OJW's regex for filtering.

This also generates 10 passphrase sets, allows passing command-line parameters to adjust the number of words, and adds number and symbol padding (also adjustable length).

Sample times for this script:

real    0m0.289s
user    0m0.176s
sys     0m0.108s

Usage: xkcdpass-mod.py 2 4 (for example; these are the default values).

It prints spaces in the output for easy reading, although I've almost never encountered an online service that allows using them, so I would just ignore them. This could definitely be cleaned up with argparse or getopt and allowing switches for including spaces or not, including/excluding symbols, capitals, etc., plus some additional refactoring, but I haven't gotten to that yet. So, without further ado:

#!/usr/bin/env python
#Copyright AMH, 2013; dedicated to public domain.
import os, re, sys, random
from sys import argv

def getargs():
    if len(argv) == 3:
        numwords = argv[1]
        numpads = argv[2]
        return(numwords, numpads)
    elif len(argv) == 2:
        numwords = argv[1]
        numpads = 4
        return (numwords, numpads)
    else:
        numwords = 2
        numpads = 4
        return (numwords, numpads)

def dicopen(dictionary="/usr/share/dict/american-english"):
    f = open(dictionary, "r")
    dic = f.readlines()
    return dic

def genPassword(numwords, numpads):
    r = random.SystemRandom()
    pads = '0123456789!@#$%^&*()'
    padding = []
    words = dicopen()
    wordlist = []
    for i in range (0,int(numpads)):
        padding.append(pads[r.randint(0,len(pads)-1)])
    #initialize counter for only adding filtered words to passphrase
    j = 0
    while (j < int(numwords)):
        inclusion_criteria = re.compile('^[a-z]{5,10}$')
        #Select a random number, then pull the word at that index value, rather than looping through the dictionary for each word
        current_word = words[r.randint(0,len(words)-1)].strip()
        #Only append matching words
        if inclusion_criteria.match(current_word):
            wordlist.append(current_word)
            j += 1
        else:
        #Ignore non-matching words
            pass
    return(" ".join(wordlist)+' '+''.join(padding))

if(__name__ == "__main__"):
    for i in range (1,11):
       print "item "+str(i)+"\n"+genPassword(getargs()[0], getargs()[1])

Sample output:

[✗]─[user@machine]─[~/bin]
└──╼ xkcdpass-mod.py
item 1
digress basketball )%^)
item 2
graves giant &118
item 3
impelled maniacs ^@%1

And going for the full "correct horse battery staple" (CHBS), no padding:

┌─[user@machine]─[~/bin]
└──╼ xkcdpass-mod.py 4 0
item 1
superseded warred nighthawk rotary 
item 2
idealize chirruping gabbing vegan 
item 3
wriggling contestant hiccoughs instanced 

According to https://www.grc.com/haystack.htm, for all practical purposes, assuming 100 trillion guesses per second (i.e., 100 TH/s) the shorter version would take about 50-60 million centuries to crack; the full CHBS = 1.24 hundred trillion trillion centuries; adding padding to that, 15.51 trillion trillion trillion centuries.

Even enlisting the entire Bitcoin mining network (~2500 TH/s as of this writing), the short version would still likely take 250-300 million years to break, which is probably secure enough for most purposes.

share|improve this answer
    
Your estimate of "50-60 million centuries to crack" the passphrase "graves giant &118" (apparently) is a huge mistake. You must assume (as Randall did) that the attacker is generating guesses the same way you are - by picking random words from the dictionary. Randall calculates 44 bits of entropy even for 4 words. Also, taking an extra 3 seconds to run a program like this hardly matters. –  nealmcb Sep 7 at 2:13
    
And your pads are hard to remember but easy to crack since there are only 20 possibilities for each character (less than a lower case letter of the alphabet!), so only about 4 bits of entropy each. Given your cracking speed assumption, cracking a 4-word password like Randall's with 44 bits of entropy would take less than a second, and cracking one like your 2-word example plus 4 random pads would be far easier (only about 22+4*4 = 38 bits of entropy). –  nealmcb Sep 7 at 2:38

This is more for fun than anything. Scores favorably in passwordmeter.com but impossible to remember.

#!/usr/bin/ruby

puts (33..126).map{|x| ('a'..'z').include?(x.chr.downcase) ?
                       (0..9).to_a.shuffle[0].to_s + x.chr :
                       x.chr}.uniq.shuffle[0..41].join[0..41]
share|improve this answer

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