# Checking that floating points arguments are correct

I want to write a class representing Markov chain (let's name it `MC`). It has a constructor, which takes the state transition matrix (that is, `vector<vector<double>>`. I suppose, it is a good idea to check it is really a matrix (has the same number of rows and columns) and is really a transition matrix: all the numbers in it are probabilities, that is, no less than `0.0` and no greater than `1.0`, and for every row the sum of its elements is `1.0`. However, there is a problem which arises from floating point limitations: for example, the sum `0.3 + 0.3 + 0.3 + 0.1` will not be equal to `1.0`, so the check will not be that easy. So I see two possible solutions of that problem:

1. Choose some epsilon and compare with epsilon error. Of course it will now accept some matrices violating the transition matrix property, but in general, if someone occasionally passes some bad data into the constructor, he will get an exception.
2. Don't check anything, rely on the class' user, if he passes something bad, it is completely his fault, and the behavior of the class will be unexpected.

What approach is better and more "real-world"? I like the first, but again, not sure how should I choose epsilon.

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1st is better. 2nd is real-world and by this I mean that we've got lots of poor code worldwide. Code defensively, if you care. Don't, otherwise. –  Alexey Frunze Apr 13 '13 at 5:03
Clearly the first option is better, however, I'd suggest adding a subtlety if small deviations from the criteria are likely to be a problem: the constructor could have an option that allows it to store a corrected transition matrix that has one or more of the elements in each row modified so that the sum of the elements is as close to `1.0` as possible. There are precedents for this in popular libraries, e.g. functions that take an array of probabilities `a` and normalise each element of the array to equal `a[i]/sum(a)` to deal with the case where the elements of `a` do not add to `1.0`. –  Simon Apr 13 '13 at 5:48
@simon clearly? Looks clear the other way to my eyes. –  David Heffernan Apr 13 '13 at 6:12
@DavidHeffernan: I find that if faulty input to a function causes the function to throw an exception or crash immediately, that makes it a lot easier to find the bugs that caused the faulty input. If the first sign of a problem doesn't turn up until a long time later, it could take a lot of debugging to find the root cause. Where consistency checking causes too much overhead for production code, I'll turn the checking off for production but, if it doesn't slow things down unduly, I like to keep the checking in the production code too. –  Simon Apr 13 '13 at 6:23
@simon in this scenario it seems impossible to agree on the definition of faulty and when that is so my experience tells me that trying to validate will juat lead to false positives and stroppy users –  David Heffernan Apr 13 '13 at 6:32

Do the second one.

Your class isn't in the business of summing up lists of floating-point numbers and deciding what's "close enough" to 1 and what isn't. Your user is. Your class represents Markov chains. You won't be able to choose a value of epsilon so that your class represents Markov chains in a useful way.

Think about the operations you're going to implement. Maybe you're going to have a function that hits a probability distribution on the states of the chain with the chain's transition matrix. Should that function check whether the input probability distribution is a probability distribution within some epsilon?

Your function almost certainly won't preserve the "is a probability distribution" property; you'll get some drift due to rounding error away from the space of probability distributions as you repeatedly hit your probability distribution by your Markov chain. You can correct this by normalising afterward, but that causes even more inaccuracy.

Now think about the "given a Markov chain and an integer k, return the Markov chain formed by iterating the input chain k times" operation. You can see that this will accumulate roundoff and suffer from much the same problems as "hit probability distribution with Markov chain."

Wouldn't it suck if you only had a choice between stuff that breaks after 12 hours of use and stuff that's unnecessarily inaccurate?

(Checking the squareness and matrixness of the square matrix argument is, of course, totally reasonable.)

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+1 the user of your code can't get anywhere if they send bogus inputs so let them take care of getting it right –  David Heffernan Apr 13 '13 at 6:12
Could have a helper function in the class called "check()" or something that gives a "score" (or "true"/"false") result based on whether it is a "good" matrix or not. –  Mats Petersson Apr 13 '13 at 7:38