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I have some code which delivers things based on weighted random. Things with more weight are more likely to be randomly chosen. Now being a good rubyist I of couse want to cover all this code with tests. And I want to test that things are getting fetched according the correct probabilities.

So how do I test this? Creating tests for something that should be random make it very hard to compare actual vs expected. A few ideas I have, and why they wont work great:

  • Stub Kernel.rand in my tests to return fixed values. This is cool, but rand() gets called multiple times and I'm not sure I can rig this with enough control to test what I need to.

  • Fetch a random item a HUGE number of times and compare the actual ratio vs the expected ratio. But unless I can run it an infinite number of times, this will never be perfect and could intermittently fail if I get some bad luck in the RNG.

  • Use a consistent random seed. This makes the RNG repeatable but it still doesn't give me any verification that item A will happen 80% of the time (for example).

So what kind of approach can I use to write test coverage for random probabilities?

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Could you expand on the final objection? Why can't you test your distribution curve with a seeded PRNG? –  DigitalRoss May 20 '11 at 22:16
    
@DigitalRoss Because it's still random. So if I get the thing I want 3 out of 10 times doesn't actually tell if I satisfied a 25% probability. Knowing the random values ahead of time doesn't really help. –  Alex Wayne May 20 '11 at 22:54

4 Answers 4

up vote 7 down vote accepted

I think you should separate your goals. One is to stub Kernel.rand as you mention. With rspec for example, you can do something like this:

test_values = [1, 2, 3]
Kernel.stub!(:rand).and_return( *test_values )

Note that this stub won't work unless you call rand with Kernel as the receiver. If you just call "rand" then the current "self" will receive the message, and you'll actually get a random number instead of the test_values.

The second goal is to do something like a field test where you actually generate random numbers. You'd then use some kind of tolerance to ensure you get close to the desired percentage. This is never going to be perfect though, and will probably need a human to evaluate the results. But it still is useful to do because you might realize that another random number generator might be better, like reading from /dev/random. Also, it's good to have this kind of test because let's say you decide to migrate to a new kind of platform whose system libraries aren't as good at generating randomness, or there's some bug in a certain version. The test could be a warning sign.

It really depends on your goals. Do you only want to test your weighting algorithm, or also the randomness?

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This was the cognitive piece I was missing. Using multiple return values like that for the rand stub got me what I needed. I can now test a predictable and perfectly even distribution of values and ensure that they do the right thing. Thanks! –  Alex Wayne May 20 '11 at 22:58

It's best to stub Kernel.rand to return fixed values.

Kernel.rand is not your code. You should assume it works, rather than trying to write tests that test it rather than your code. And using a fixed set of values that you've chosen and explicitly coded in is better than adding a dependency on what rand produces for a specific seed.

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If you wanna go down the consistent seed route, look at Kernel#srand:

http://www.ruby-doc.org/core/classes/Kernel.html#M001387

To quote the docs (emphasis added):

Seeds the pseudorandom number generator to the value of number. If number is omitted or zero, seeds the generator using a combination of the time, the process id, and a sequence number. (This is also the behavior if Kernel::rand is called without previously calling srand, but without the sequence.) By setting the seed to a known value, scripts can be made deterministic during testing. The previous seed value is returned. Also see Kernel::rand.

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For testing, stub Kernel.rand with the following simple but perfectly reasonable LCPRNG:

@@q = 0
def r
  @@q = 1_103_515_245 * @@q + 12_345 & 0xffff_ffff
  (@@q >> 2) / 0x3fff_ffff.to_f
end

You might want to skip the division and use the integer result directly if your code is compatible, as all bits of the result would then be repeatable instead of just "most of them". This isolates your test from "improvements" to Kernel.rand and should allow you to test your distribution curve.

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You have just blown my mind… But I can't figure out how this generates randomness. –  Michael Irey May 8 at 21:53

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