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I am playing around with PRNGs (like Mersenne Twister and rand() function of stdlib) and I would want a good test that would help me ascertain the quality of random data produced by the PRNGs. I have calculated the value of Pi using random numbers generated by the PRNGs, and I find rand() and Mersenne Twister to be very close to offer a distinction (do I need to scrutinize after 10 decimal points?).

I do not have much idea about Monte Carlo simulations; please let me know about some algorithm/application (possibly something simple yet which could provide good inferences) that would help me distinguish them in terms of quality.

Thank you.

EDIT - 1: I didn't notice before, but there is a similar thread: How to test random numbers?

EDIT - 2: I am not able to interprete the results of NIST, as mentioned in one of the comments. I got this idea of visually interpreting the pattern (if any) from random.org - http://www.random.org/analysis/ and am following that because of it's simplicity. I would be very glad if someone could comment on the process of my testing:

  1. Generate N randoms from [0,1] using rand() and MT1997
  2. if (round(genrand_real1() / rand_0_1())) then red pixel, else black

As I understand that this is not a very precise solution, but if this provides a reasonable estimate, then I could live with this at the present moment.

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i'm not so sure about getting any random data from pseudorandom number generators - but i think you could implement en.wikipedia.org/wiki/Fair_coin#Fair_results_from_a_biased_coin with them.. – Aprillion Mar 20 '12 at 1:36
    
are you saying that because the values generated from PRNGs are predictable? thank you – Sayan Mar 20 '12 at 1:40
    
yes, that is the distinction - it was just a reminder for you to check whether a PRNG is good enought for your application and you don't need a TRNG like random.org – Aprillion Mar 20 '12 at 11:14
up vote 4 down vote accepted

There are two standard test suites for testing random numbers.

  1. NIST test suite. They have an implementation in C.
  2. Diehard Test Suite (developed by George Marsaglia). There is a C library implementation of these tests.

There is a R interface to the Dieharder library, called RDieHarder. This library provides an interface to both the NIST and Diehard test suites.

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I am using NIST, but I think although my test passes, there's some problem; can you please help? - I have generated long random values, and converted them to binary and stored in a file. Say 100 randoms are there in the file, I do assess 100 and follow the steps in the "Running the Test Code" section of the doc (chose the bit streams generated to be 10 as in the doc). But I see that my "finalAnalysisReport.txt" for the default test case contains almost no info. – Sayan Mar 21 '12 at 15:39
    
Your best bet is to ask another question. – csgillespie Mar 21 '12 at 21:27

You're best off looking into the volume 2 of the Knuth's series.

For a shorter read, look up the corresponding chapter of the Numerical Recipes.

If you're only interested in a sort of a baseline for a MC simulation--- linear congruential generators are best avoided, Mersenne Twister is good enough in the vast majority of cases.

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Can you give a link to evidence for the claim that LGCs are best avoided for Monte-Carlo simulations? – ziggystar Aug 19 '13 at 8:58
    
@ziggystar: well, you can look up in Knuth. Or Numerical Recipes. Or google up the results the standard test suites, eg from the csgillespie answer. – ev-br Sep 20 '13 at 23:38

There are several statistical tests suites available. I wrote, copied, and otherwise gathered together 120 PRNGs and tested each with a variety of tests suites:

The test suite used:

PractRand - http://pracrand.sourceforge.net/
TestU01 - http://simul.iro.umontreal.ca/testu01/tu01.html
RaBiGeTe - http://cristianopi.altervista.org/RaBiGeTe_MT/
Dieharder - http://www.phy.duke.edu/~rgb/General/dieharder.php
NIST STS - http://csrc.nist.gov/groups/ST/toolkit/rng/documentation_software.html

given 4 hours per PRNG per test suite:

PractRand (standard, 1 terabyte) found bias in 78 PRNGs
TestU01 (BigCrush) found bias in 50 PRNGs
RaBiGeTe (extended, 512 megabit, x1) found bias in 40 PRNGs
Dieharder (custom command line options) found bias in 25 PRNGs
Dieharder (-a command line option) found bias in 13 PRNGs
NIST STS (default, 64 megabit x128) found bias in 11 PRNGs

How many of those were in PRNGs that the other test suites all missed?

PractRand (standard, 1 terabyte) found 22 unique biases, in a wide variety of categories.  
RaBiGeTe (extended, 512 megabit, x1) found 5 unique biases, all in LCGs and combination LCGs.  
TestU01 BigCrush found 2 unique biases, both in small chaotic PRNGs.  
No other test suite found any unique biases.  

In short, only PractRand, TestU01, and possibly RaBiGeTe are worth using.

Full disclosure: I wrote PractRand, so either the set of PRNGs or any other non-qualitative measure could be biased in its favor.

miscellaneous advantages: PractRand and TestU01 tend to be the easiest to interpret the output of in my opinion. PractRand and Dieharder tend to be the easiest to automate testing for via command line interface I think. PractRand and RaBiGeTe were the only ones to support multithreaded testing.

miscellaneous disadvantages: PractRand required more bits of input to test than other test suites - could be a problem if your RNG is very slow or otherwise limited on amount of data produced. RaBiGeTe and NIST STS both have interface issues. Dieharder and NIST STS both have false-positive issues. NIST STS had the worst interface in my opinion. I could not get Dieharder to compile on Windows. I managed to get TestU01 to compile on windows but it took some work. Recent versions of RaBiGeTe are closed-source and windows-only.

the set of PRNGs tested: The PRNG set includes 1 large GFSR, 1 large LFSR, 4 xorshift type PRNGs, 2 xorwow type PRNGs, 3 other not-quite-LFSR PRNGs. It includes 10 simple power-of-2 modulus LCGs (which discard low bits to reach acceptable quality levels), 10 power-of-2 modulus not-quite-LCGs, and 9 combination generators based primarily around LCGs and not-quite-LCGs. It includes 19 reduced strength versions of CSPRNGs, plus one full strength CSPRNG. Of those, 14 were based upon indirection / dynamic s-boxes (e.g. RC4, ISAAC), four were ChaCha/Salsa parameterizations, and the remaining 2 were Trivium variants. It includes 11 PRNGs broadly classifiable as LFib-type or similar, not counting the LFSRs/GFSRs. The rest (about 35) were small state chaotic PRNGs, of which 10 used multiplication and the others were limited to arithmetic and bitwise logic.

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