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I need to create a one-time pad to encrypt some data (a few KBs in size). How should I go about generating this one-time pad to avoid all of the pseudo-random problems associated with basic random number generation such as rand()?

Is there an existing, trusted tool or library I can use for this?

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What language / operating system / runtime environment are you using? – Erik Forbes Jan 12 '11 at 18:21
look here for a couple of good solutions:… – Peter G. Jan 12 '11 at 18:41
@Erik, doesn't matter too much. Preferably Windows, though. – pate Jan 13 '11 at 7:43
up vote 4 down vote accepted

Try Random.ORG. They have various free (and paid) services that generate truly random numbers based on atmospheric noise (or at least that is what they claim to do).

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This looks promising. – pate Jan 13 '11 at 7:42
As long as you don't mind someone else knowing your super-secret one time pad. And you don't mind your attackers being able to intercept it on the wire. – Nick Johnson Jan 16 '12 at 3:11

You can't generate truly random numbers algorithmically - you need hardware assistance. If you use an algorithm, however secure (such as a cryptographically secure PRNG), you're simply creating a stream cipher based on that PRNG; it's no longer a One Time Pad.

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@Nick: While using a cryptographically-secure PNRG for a one-time pad is not the same as using a true RNG, the two methods are almost identical in strength. It's not called "cryptographically-secure" for nothing. And I like Steve Bellovin's quote: "I've observed that one-time pads are theoretically unbreakable, but practically very weak. By contrast, conventional ciphers are theoretically breakable, but practically strong." – RoadWarrior Jan 15 '11 at 16:43
No, they're not 'almost identical in strength'. A real OTP, used properly, is literally unbreakable, since all plaintexts are equally probable. In contrast, a cryptographically secure PRNG has a much more limited state. The OP almost certainly actually wants a conventional cipher - OTPs are very rarely the correct answer - but simply saying "use a PRNG" is bad advice: you're just inventing your own cipher based on the PRNG, and you'd be far better off using an existing cipher. – Nick Johnson Jan 16 '11 at 1:57
There is no such thing as a guaranteed "real OTP". Security is defined only relative to an attack model. For example, a hardware circuit to produce subverted bits can be built on an integrated circuit a few millimeters square. The most sophisticated hardware random number generator can be subverted by placing such a chip anywhere upstream of where the source of randomness is digitised, say in an output driver chip or even in the cable connecting the RNG to the computer. – RoadWarrior Jan 17 '11 at 18:27
@RoadWarrior Yes there is. Don't confuse difficulty of implementation or verification with theoretical impossibility. And this is totally irrelevant: whether or not it's practical to achieve a 'true' OTP, using a PRNG is most assuredly not one. – Nick Johnson Jan 17 '11 at 22:53
The fundamental security of an OTP is based on having a set of numbers where the sequence is completely unpredictable. Regardless of the source of the numbers (a RNG or a PRNG), the unpredictability of the sequence can be compromised by an attacker with sufficient access. My example above highlights subverting an RNG, there's an academic paper that shows a similar method of subverting CryptGenRandom. Hence my use of the word "guaranteed" - both a RNG (real OTP) and a PNRG (pseudo OTP) have no guarantee of producing an uncompromised sequence of random numbers. – RoadWarrior Jan 18 '11 at 14:58

Most modern operating systems have a cryptographically-secure pseudo-random number generator.

For example, Windows has CryptGenRandom. You can access the same stream from .NET by using the RNGCryptoServiceProvider class. From C++, you can access the same stream by using the Microsoft C++ library function rand_s. From Python, it's accessible using the function urandom (see bottom of linked page) in the os module.

Unlike normal PRNGs, CSPRNGs are designed to pass rigorous statistical randomness tests. They're also designed to hold up well under serious attack, even when their initial or running state becomes available to an attacker.

The term "pseudo-random", as used by cryptographers, may be misleading to a non-technical reader. A CSPRNG expands a collection of random values, known as a seed, into a longer sequence of numbers. That sequence is reproducible given the seed, but for any good CSPRNG, a minor change in the seed yields a very different sequence. Therefore, as long as at least some portion of the seed is chosen via an adequately random process, an attacker is unable to predict the resulting sequence - even if the attacker can influence the remainder of the seed.

Numerous important systems, ranging from military communications to the encryption that protects virtually all online transactions, rely on the functionally-equivalent security between "cryptographically-secure pseudo-random" and "random".

EDIT: If you're lucky enough to be working with Intel's Ivy Bridge processor range, you now have another very interesting alternative.

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