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import string,random,platform,os,sys
def rPass():
    sent =  os.urandom(random.randrange(900,7899))
    print sent,"\n"
    for i in sent:
        intsent += ord(i)
    print intsent

I need help figuring out total possible outputs for the bytecode section of this algorithm. Don't worry about the for loop and the ord stuff that's for down the line. -newbie crypto guy out.

share|improve this question
Side note: You don't have to do random.shuffle(li, random.random); that's already the default value. And likewise, there's rarely any point mixing up os.urandom and the random module; that's what random.SystemRandom is there for. –  abarnert Mar 21 '13 at 1:08
More importantly, what does your question mean? What is "the unicode section of this algorithm"? There is no Unicode anywhere in the code, just integers and byte strings. –  abarnert Mar 21 '13 at 1:09
bytecode, sry bout that. –  Chrome Xavier Mar 21 '13 at 2:04
I don't think you mean bytecode any more than you meant Unicode. You just mean "bytes"? –  abarnert Mar 22 '13 at 1:17
there a difference? –  Chrome Xavier Mar 22 '13 at 18:11
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1 Answer

I won't worry about the loop and the ord stuff, so let's just throw that out and look at the rest.

Also, I don't understand "I need help figuring out total possible outputs for the unicode section of this algorithm", because there is no Unicode section of the algorithm, or in fact any Unicode anything anywhere in your code. But I can help you figure out the total possible outputs of the whole thing. Which we'll do by simplifying it step by step.


for a in range(900,7899):

This is exactly equivalent to:

li = range(900, 7899)



Because li happens to be exactly 6999 elements long, this is exactly the same as random.choice(li).

And, putting the last two together, this means it's equivalent to:


… which is equivalent to:


But wait, what about that random.shuffle(li, random.random)? Well (ignoring the fact that random.random is already the default for the second parameter), the choice is already random-but-not-cryptographically-so, and adding another shuffle doesn't change that. If someone is trying to mathematically predict your RNG, adding one more trivial shuffle with the same RNG will not make it any harder to predict (while adding a whole lot more work based on the results may make a timing attack easier).

In fact, even if you used a subset of li instead of the whole thing, there's no way that could make your code more unpredictable. You'd have a smaller range of values to brute-force through, for no benefit.

So, your whole thing reduces to this:

sent = os.urandom(random.randrange(900, 7899))

The possible output is: Any byte string between 900 and 7899 bytes long.

The length is random, and roughly evenly distributed, but it's not random in a cryptographically-unpredictable sense. Fortunately, that's not likely to matter, because presumably the attacker can see how many bytes he's dealing with instead of having to predict it.

The content is random, both evenly distributed and cryptographically unpredictable, at least to the extent that your system's urandom is.

And that's all there is to say about it.

However, the fact that you've made it much harder to read, write, maintain, and think through gives you a major disadvantage, with no compensating disadvantage to your attacker.

So, just use the one-liner.

I think in your followup questions, you're asking how many possible values there are for 900-7898 bytes of random data.

Well, how many values are there for 900 bytes? 256**900. How many for 901? 256**901. So, the answer is:

sum(256**i for i in range(900, 7899))

… which is about 2**63184, or 10**19020.

So, 63184 bits of security sounds pretty impressive, right? Probably not. If your algorithm has no flaws in it, 100 bits is more than you could ever need. If your algorithm is flawed (and of course it is, because they all are), blindly throwing thousands more bits at it won't help.

Also, remember, the whole point of crypto is that you want cracking to be 2**N slower than legitimate decryption, for some large N. So, making legitimate decryption much slower makes your scheme much worse. This is why every real-life working crypto scheme uses a few hundred bits of key, salt, etc. (Yes, public-key encryption uses a few thousand bits for its keys, but that's because its keys aren't randomly distributed. And generally, all you do with those keys it to encrypt a randomly-generated session/document key of a few hundred bits.)

One last thing: I know you said to ignore the ord, but…

First you can write that whole part as intsent=sum(bytearray(sent)).

But, more importantly, if all you're doing with this buffer is summing it up, you're using a lot of entropy to generate a single number with a lot less entropy. (This should be obvious once you think about it. If you have two separate bytes, there are 65536 possibilities; if you add them together, there are only 512.)

Also, by generating a few thousand one-byte random numbers and adding them up, that's basically a very close approximation of a normal or gaussian distribution. (If you're a D&D player, think of how 3D6 gives 10 and 11 more often than 3 and 18… and how that's more true for 3D6 than for 2D6… and then consider 6000D6.) But then, by making the number of bytes range from 900 to 7899, you're flattening it back toward a uniform distribution from 700*127.5 to 7899*127.5. At any rate, if you can describe the distribution you're trying to get, you can probably generate that directly, without wasting all this urandom entropy and computation.

It's worth noting that there are very few cryptographic applications that can possibly make use of this much entropy. Even things like generating SSL certs use on the order of 128-1024 bits, not 64K bits.

You say:

trying to kill the password.

If you're trying to encrypt a password so it can be, say, stored on disk or sent over the network, this is almost always the wrong approach. You want to use some kind of zero-knowledge proof—store hashes of the password, or use challenge-response instead of sending data, etc. If you want to build a "keep me logged in feature", do that by actually keeping the user logged in (create and store a session auth token, rather than storing the password). See the Wikipedia article password for the basics.

Occasionally, you do need to encrypt and store passwords. For example, maybe you're building a "password locker" program for a user to store a bunch of passwords in. Or a client to a badly-designed server (or a protocol designed in the 70s). Or whatever. If you need to do this, you want one layer of encryption with a relatively small key (remember that a typical password is itself only about 256 bits long, and has less than 64 bits of actual information, so there is absolutely no benefit from using a key thousands of times as long as they). The only way to make it more secure is to use a better algorithm—but really, the encryption algorithm will almost never be the best attack surface (unless you've tried to design one yourself); put your effort into the weakest areas of the infrastructure, not the strongest.

You ask:

Also is urandom's output codependent on the assembler it's working with?

Well… there is no assembler it's working with, and I can't think of anything else you could be referring to that makes any sense.

All that urandom is dependent on is your OS's entropy pool and PRNG. As the docs say, urandom just reads /dev/urandom (Unix) or calls CryptGenRandom (Windows).

If you want to know exactly how that works on your system, man urandom or look up CryptGenRandom in MSDN. But all of the major OS's can generate enough entropy and mix it well enough that you basically don't have to worry about this at all. Under the covers, they all effectively have some pool of entropy, and some cryptographically-secure PRNG to "stretch" that pool, and some kernel device (linux, Windows) or user-space daemon (OS X) that gathers whatever entropy it can get from unpredictable things like user actions to mix it into the pool.

So, what is that dependent on? Assuming you don't have any apps wasting huge amounts of entropy, and your machine hasn't been compromised, and your OS doesn't have a major security flaw… it's basically not dependent on anything. Or, to put it another way, it's dependent on those three assumptions.

To quote the linux man page, /dev/urandom is good enough for "everything except long-lived GPG/SSL/SSH keys". (And on many systems, if someone tries to run a program that, like your code, reads thousands of bytes of urandom, or tries to kill the entropy-seeding daemon, or whatever, it'll be logged, and hopefully the user/sysadmin can deal with it.)

hmmmm python goes through an interpreter of its own so i'm not sure how that plays in

It doesn't. Obviously calling urandom(8) does a bunch of extra stuff before and after the syscall to read 8 bytes from /dev/urandom than you'd do in, say, a C problem… but the actual syscall is identical. So the urandom device can't even tell the difference between the two.

but I'm simply asking if urandom will produce different results on a different architecture.

Well, yes, obviously. For example, Linux and OS X use entirely different CSPRNGs and different ways of accumulating entropy. But the whole point is that it's supposed to be different, even on an identical machine, or at a different time on the same machine. As long as it produces "good enough" results on every platform, that's all that matters.

For instance would a processor\assembler\interpreter cause a fingerprint specific to said architecture, which is within reason stochastically predictable?

As mentioned above, the interpreter ultimately makes the same syscall as compiled code would.

As for an assembler… there probably isn't any assembler involved anywhere. The relevant parts of the Python interpreter, the random device, the entropy-gathering service or driver, etc. are most likely written in C. And even if they were hand-coded in assembly, the whole point of coding in assembly is that you pretty much directly control the machine code that gets generated, so different assemblers wouldn't make any difference.

The processor might leave a "fingerprint" in some sense. For example, I'll bet that if you knew the RNG algorithm, and controlled its state directly, you could write code that could distinguish an x86 vs. an x86_64, or maybe even one generation of i7 vs. another, based on timing. But I'm not sure what good that would do you. The algorithm will still generate the same results from the same state. And the actual attacks used against RNGs are about attacking the algorithm the entropy accumulator, and/or the entropy estimator.

At any rate, I'm willing to bet large sums of money that you're safer relying on urandom than on anything you come up with yourself. If you need something better (and you don't), implement—or, better, find a well-tested implementation of—Fortuna or BBS, or buy a hardware entropy-generating device.

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@ChromeXavier: Before you clarify, maybe explain what you're actually trying to do before diving into the code that you hope will do it. –  abarnert Mar 21 '13 at 1:37
damn, and yessir. the question of "total possible" though, I want to know maximum possible outcomes. in responce to "Before you clarify, maybe explain what you're actually trying to do before diving into the code" I can't tell you too much but let me think of a concise answer for that. –  Chrome Xavier Mar 21 '13 at 1:55
the bytes combines with the ord will act together in a key-lock mechanism unfolding a secondary and third layer of crypto underneath. the first and second are of my own making, the third will be well known and established, ECC most likly. –  Chrome Xavier Mar 21 '13 at 1:59
tryin to do it on paper... i just dont remember the maths, anyone? –  Chrome Xavier Mar 21 '13 at 2:09
is it a permutation of 7000!/(7000-256)! ? –  Chrome Xavier Mar 21 '13 at 2:36
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