I need to test a random number generator which produces numbers randomly. How to make sure the numbers generated are random.
Here is a detailed explanation of how to start. The preliminary test for any RNG is the Monobit test used by the NIST which simply counts the number of 1s and 0s. http://csrc.nist.gov/groups/ST/toolkit/rng/stats_tests.html
A note about testing a Random Number Generator: We actually don't need too many RNG tests because many "subsume" one another.
That said, described here is a simple effective new Ordered Frequency Test for bits. This test subsumes any frequency test that expects 50-50 because it is more stringent.
Definitions: t= tosses / trials b=bins / urns s=sessions of tosses n=sets of sessions
Because coin tosses are usually not 50-50, this new test can be utilized with great effectiveness using a pool of 40,000,000 bits.
When coins are flipped 100 times, the expected values are 53.9795 of one and 46.0205 of the other, sometimes more heads, sometimes more tails. 50-50 is not the expected value of the ordered bins, so this test is superior to any frequency test that instead expects 50-50.
Step 1: Choice of sample size: 100 tosses / bits.
Step 2: Choice of number of Sessions: 50 sessions is never sufficient, even with huge sample sizes in the millions. 400 is usually enough. 2000 converges well, so 2000 different samples of 100 tosses are used. Minimal gain occurs above 2000.
Expected values for 2000 sessions of 100 tosses:
50-50 159.1784748 (Notice that 50-50 occurs a mere 7.96% of the time.)
The equation to obtain the exact percentages for bins b=2 and tosses t=100 is: For 100-0, the odds are 1 / (2^99) = 1 / (2^(t-1)) Then, building up from there, for 99-1 previous multiplied by 100 (t) divide by 1 for 98-2 previous multiplied by 99 (t-1) divide by 2 for 97-3 previous multiplied by 98 (t-2) divide by 3 ... skip ... for 51-49 previous multiplied by 52 (t-48) divide by 49 for 50-50 previous multiplied by 51 (t-49) divide by 50, then divide again by 2.
This equation works with any number of tosses.
Step 3: A chi-square is taken on these 18 values with 17 degrees of freedom giving a resulting p value.
p values above 0.999 are close to perfection. Can an RNG be too close to perfection too often? Yes, being too predictable. Under 0.001 is where definite problems usually occur. One test suite considers 300 zeroes to the right of the decimal as infinitesimally bad and 10-14 in a row as quite bad. Some consider 6 zeroes bad enough to qualify as a definite clear failure. Some, for the sake of safety, consider 1 or 2 zeroes enough and they are in error. So, instead of a single p value for a single set sometimes providing a p value below 0.01 for an excellent RNG, many sets of sessions are taken.
Step 4: The p values are fed to a 0-1.0 straight line Kolmogorov-Smirnov test. Different experts recommend the number of inputs to the K-S test to be from 10 to 1000. 100 is not quite enough. 200 is fine. 500 is slightly aggressive.
Here is pseudocode to obtain the K-S maximum difference:
The K-S answer is not a p value and should not exceed 0.115 for 200 p values. 0.03 to 0.08 is normal for a good RNG. 0.115 to 0.13 is suspect.
The K-S test is very simple It is also quite effective.
Shown above is a superior new Ordered Frequency Test. Any RNG which fails this test should not be tested further and immediately replaced. But, what next?
The OFTest does not subsume the LOR test. Recommended is the Length Of Runs test with sample size 200,000 with 15 degrees of freedom fed into the K-S test 200 times. (Note that the expected total of the smallest LOR bin for "more than j" is equal to the jth bin.)
And then what? For many games, these two tests are all you need. There are a propensity of choices from NIST, Diehard, Dieharder, Crusher. (Note: The Diehard Overlapping Sums test is both inferior and faulty, not a faithful interpretation of Marsaglia's original Fortran code.)
Results from a few RNGs with n=200.
Notice that the low bits of any and every LCG should be discarded from the returned result.
A note about 2^35: This is the minimum period and significance for any RNG because coin flips and craps runs and such things can happen 30 times in a row, but 35 just isn't expected to happen. A period of 2^32 is insufficient, too small for real life situations.
You can only test statistical randomness anyway, and that does not prove whether the number sequence is cryptographically strong. Statistically testing a PRNG requires quite a lot (10 or even 100Gbytes) of the generated bits.
Dieharder is a very good testing suite.
And TestU01 is also well-known.
It depends how severe your requirement for randomness is. If it is not too severe, what I do is generate a large number of random numbers, find their frequencies and then use the frequencies to plot a graph using a spreadshhet like that in Open Office. If the distribution looks OK, then I'm good to go.
Unless you have access to the random number generator and can use it to generate numbers at will, you can't test if a sequence of numbers is random. Think about it: you have a random number generator. Let's say it's a uniform random number generator, generating random integers in the range [0,9]. Given a sequence:
can you tell if it is random? There is a finite probability 10−10, that our uniform random number generator will generate this exact sequence. In fact, given any length-10 sequence, we have the same probability of our uniform random number generator generating that sequence. Hence, by definition, you can't determine if a given sequence is random.
If you do have access to the generator itself, and can use it to generate multiple sequences, then it makes sense to "check for randomness". For this, I would look at Diehard tests. There are various implementations.
You can't generate true randomness by any algorithm, thus try to visualize your outputs and check for patterns with your own eyes. None random generator (by algorithm) would create some patterns that you can judge them yourself. Here is one of demonstration of that idea: http://www.alife.co.uk/nonrandom/
You can't make sure, there is no way to distinguish with certainty any function from a random number generator using a finite number of tests. But you can do Statistical Analysis:
See the section on Charmaine Kenny's study for more details on the tests you could run.
Create a log file which will contains the random number for atleast 500 instances and audit it for randomness. Also have a look at below link,
Use chi-square testing. What language are you using? I can offer a C++ example. Basically
Often if you have your generator draw dots at random locations in a bitmap, any nonrandomness will easily be discernable to the eye as clumping, banding or lines.
You cannot ensure the numbers are random simply because random numbers are, well, random.
The chances of getting a string of one million consecutive 9's is the same as getting any other specific one-million-long sequence. The one thing you can check for is correct distribution over a large sample set. Run a sizeable test and work out the relative occurrences of each possible outcome.
Over a large enough sample, they should be roughly the same.
One other possibility is to test for non-repeatability. Ideally, random numbers should not depend on the numbers that came before. Very simple (linear congruential) PRNGs will most likely give you the same sequence of numbers eventually but over a large enough set that you probably won't care (unless you're serious about randomness).
It's a very difficult thing.
This also looks interesting: Diehard tests (I've not worked with it though).