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roganjosh

03:03

cv-pls stackoverflow.com/questions/78469757/… dupe

7 hours later…

roganjosh

10:13

Yesterday I was at TeamLAB and multiple exhibitions have plaques saying "The projected images are infinitely varied and will never repeat; they are created by a computer algorithm that takes into account people's actions". The person I was with said - "surely if it's an algorithm, it's impossible to get infinitely variable outputs"

I scoffed and said "Sure you can. If you're taking noise from the visitors to the exhibit". But now I question whether that really is infinite in a formal sense. I feel like this should be proven/disproven somewhere. Is there a theory behind this?

Going on my pleb-level physics basis, I know that if the universe is infinite, then there should be infinitely many exact copies of me. So, there would be infinitely many repetitions of the exhibits' projections?

Especially if we assume that the universe is finite, then the noise it could generate would be finite (even if it's super-ridiculously-vanishingly small to get a repetition)

Andras Deak -- Слава Україні

I think the question is whether the state space of the exhibition display is infinite

And the likely answer is "no"

Not because "it's an algorithm" but because someone coded up that algorithm and the display has a number of pixels/voxels/whatever.

roganjosh

10:30

I hadn't even thought about the constraints of the display equipment, thanks. So actually that would make the chance of repetitions only ridiculously-vanishingly small. I'm going to write a letter of complaint for the misinformation!

(actually, it's probably one of my favourite attractions. It's a shame they closed some of the others with different themes because I would have loved to see a different one than last year)

matszwecja

Display constraints are one thing, input constraints are another - even if the physical states from the visitors are infinite, ways they are represented for an algorithm will be finite

roganjosh

10:45

@matszwecja Another thing I didn't think of :/ Of course there are a finite number of float values that a computer can work with. I should have taken more time before I made my response :(

2 hours later…

inspectorG4dget

13:11

morning cabbages folks!

@smci that's exactly what I meant. Thank you for catching my typo

PM 2Ring

13:44

@roganjosh Also output constraints. It takes a long time to enumerate all n bit patterns when n is large. Eg, it takes 64 bits to describe a simple 2 colour 8×8 pixel square. To display all the patterns at 50 frames per second takes over 11 billion years.

With 16×16 pixels, the universe will reach heat death before you could display all the patterns, even if you ran them in parallel using every atom of the observable universe. So their algorithm may not technically be infinite, but it may be effectively infinite. ;)

Hakaishin

@PM2Ring atoms and in the universe and heat death of the universe seem like reasonable upper bounds to call something infinite :D

PM 2Ring

14:01

Well, we're programmers. We're allowed to be pedantic. :)

But yeah, if your random process has a period of 2^256 I won't mind too much if you say it has endless variation.

OTOH, Mersenne Twister has a much longer period. But due to its design, you only need to see ~640 outputs (IIRC) to deduce exactly where it is in its cycle. So it's not cryptographically safe.

en.wikipedia.org/wiki/Mersenne_Twister says its period is 2^19937 - 1 but you only need to see 624 iterations to break it.

So it's a bit annoying that it's still the default RNG in the stdlib. Especially since we now have faster & smaller RNGs with better statistical properties, like PCG, which is now the default in Numpy. pcg-random.org

PCG isn't crypto-safe, either. But it's much better than Mersenne Twister for stuff like Monte Carlo based simulations.

roganjosh

15:14

@Hakaishin but that's finite. I'm used to dealing with problems that, technically, would take longer than the lifetime of the universe to solve. But that's not strictly the definition of "infinite". What confused me here was whether you could actually create an infinite number of scenarios with a computer based on noise

You could make a ruler that only measured between 0 and 1 centimetres, and there's an infinite number of gradations between the two values. But it's clear to me now that this is not possible in my case, both through the projection limitations and computer limitations

Peilonrayz

@PM2Ring Do you know any ELI5 explanations of how to break the Twister?

PM 2Ring

15:49

@Peilonrayz Sorry, no. I read about it a few years ago, but the explanation was a bit vague, and I didn't fully understand it. But I think it's essentially solving a system of equations to determine the coefficients of a polynomial.

Eg, if your poly is of the form y=ax^3 + bx^2 + cx + d, you only need 4 (x, y) pairs to determine a, b, c, d.

Peilonrayz

Ah, such a solution would make sense. Thanks.

PM 2Ring

So if you know y, the 32 bit output for each core random() call, and assume x is just the linear sequence of integers, starting at 0, after 624 calls you have enough data to determine the coefficients, which gives you the internal state of the twister.

PM 2Ring

16:07

Modern crypto hashes like Keccak (SHA-3) prevent such attacks because only part of the internal state is touched by the input or output. Wikipedia has a description, but it's not totally clear. ;) en.wikipedia.org/wiki/SHA-3

PCG64 also uses that strategy. Its I/O is 64 bits, but its internal state of 128 bits can't be deduced from a sequence of its outputs. I think. :)

From pcg-random.org/predictability.html

> Most of the PCG output functions involve nonlinear operations and only reveal partial state, but as we saw from Knuth's truncated LCGs, that's no guarantee of that PCG generators can't be cracked.

But it takes a lot of outputs, and a lot of work. And so far, nobody has met Dr O'Neill's challenge to crack PCG.

BTW, @Peilonrayz, there's a link on that last PCG page to an article on cracking Mersenne Twister.

Aran-Fey

17:05

A little game worth checking out: ncase.me/trust

paul23

17:17

To what extend do you guys split up functions in unit tests?

ie: I have an import function.. I could split it up like:
- every "value" of the imported xml is tested on itself
- test against default values, but make separate tests to see if the calculated, indirect values are done correctly (which are still params so it looks like just details)
- test everything in a single function, and just split against "good vs bad input".

Aran-Fey

17:42

I don't understand the question, could you share some code that demonstrates what/how you're testing?

paul23

def import_data(data_dict):
    self.amount = data_dict.get("amount", 0)
    self.vat_code = data_dict.get("vat", 0)
    # ...
    # post import part
    self.vat_amount = calculate_vat_based_on_code_and_country_and_type_company()

Aran-Fey

17:57

Ok, I see. I think option 3 is the correct answer: We want to test that an input of X leads to an output of Y. What happens inside of the function is all implementation details, so I wouldn't write separate tests for calculate_vat_based_on_code_and_country_and_type_company()