**Introduction**

The “Bayesian/frequentist” coin puzzle discussed in the last couple of posts was really just an offshoot of some thoughts I have been mulling over about Reddit’s current default approach to ranking user comments on a post, based on the number of upvotes and downvotes each comment receives. (Or more generally, the problem of ranking a collection of *any* items, whether comments, or consumer products, etc., based on varying numbers of “like/dislike” votes.) Instead of trying to estimate the bias of a coin based on the observed number of heads and tails flipped, here each comment is like a coin, and each upvote (or downvote) is like an observation of a coin flip coming up heads (or tails).

If we assume that each comment has some fixed– but unknown– probability that a random user will upvote the comment, then it would be convenient to simply sort all of the comments on a particular post by decreasing , so that the “best” comments would appear near the top. Unfortunately, we don’t actually know , we can only estimate it somehow by using the observed pair of upvotes and downvotes, respectively.

A natural first idea might be to “score” each comment using the maximum likelihood estimate

and sort the comments by this score. But this tends to unfairly compare comments with very different numbers of *total* votes; e.g., should a comment with votes really be ranked higher than ?

**Wilson Score Interval**

Evan Miller’s “How Not To Sort By Average Rating” does a good job of presenting this and other approaches, eventually arguing for sorting by the lower bound of the Wilson score interval, which is what Reddit currently does. Briefly, the Wilson score interval is a confidence interval intended to “cover” (i.e., contain) the *true*– but unknown– value with at least some guaranteed probability, described as the “confidence level.” In general, the *higher* the confidence level, *or* the *fewer* the number of observations, the wider the corresponding confidence interval. By scoring each comment with the lower bound of this confidence interval, we are effectively starting with a point estimate based on the fraction of upvotes, but then *penalizing* this score according to the total number of votes, with fewer votes receiving a greater penalty.

Reddit’s use of this scheme has evolved slightly over time, initially computing a 70% confidence interval, but then changing to the current wider 80% confidence interval, having the effect of imposing a slightly greater penalty on comments with fewer total votes. This “fine-tuning” of the scoring algorithm raises the question whether there might not be a more natural method for ranking user comments, that does not require this sort of knob-turning.

**A Bayesian Alternative**

Last year, James Neufeld proposed the interesting idea of sampling a *random* score for each comment by drawing from a corresponding beta distribution with parameters

The idea is that this beta distribution is a natural way to express our uncertainty about the “true” value of a comment, starting with an assumed prior *uniform* distribution on (i.e., a comment is initially equally likely to be great, terrible, or anything in between), and updating based on the observation of upvotes and downvotes, respectively. For example, a comment with 30 upvotes and 10 downvotes yields a beta distribution with the following density:

Probability density of beta distribution with parameters (30+1,10+1).

A key point is that every user does not necessarily see the comments for a post in the same order. Each time the post is viewed, the comments are *re-scored* by new random draws from the corresponding beta distributions, and sorted accordingly. As a comment receives more and more upvotes and/or downvotes, it will “settle in” to a particular position among other comments… but comments with few votes, or even strongly downvoted comments, will still have some chance of appearing near the top of any *particular* user’s view of the page.

I really like this idea, but the non-deterministic ordering of comments presented to different users may be seen as a drawback. Can we fix this?

**Sorting by Expected Rank**

I can think of two natural deterministic modifications of this approach. The first is to sort comments by their *expected* ranking using the random scoring described above. In other words, for each comment, compute the expected number of *other* comments that would appear *higher* than it on one of Neufeld’s randomly generated pages, and sort the comments by this expected value.

Although this method “fixes” the non-determinism of the original, unfortunately it suffers from a different undesirable property: the relative ranking of two comments may be affected by the presence or absence of *other* comments on the same post. For example, consider the two comments identified by their upvote/downvote counts and . If these are the only two comments on a post, then . However, if we introduce a third comment , then the resulting overall ranking is , reversing the ranking of the original two comments!

**Pairwise comparisons**

Which brings me, finally, to my initial idea for the following second alternative: sort the comments on a post according to the order relation

where

More intuitively, we are simply ranking one comment higher than another if it is more likely than not to appear higher using Neufeld’s randomized ranking.

Note one interesting property of this approach that distinguishes it from all of the other methods mentioned so far: it does not involve assigning a real-valued “score” to each *individual* comment (and subsequently sorting by that score). This is certainly possible in principle (see below), but as currently specified we can only *compare* two comments by performing a calculation involving parameters of *both* in a complex way.

**Open Questions**

Unfortunately, there are quite a few holes to be patched up with this method, and I am hoping that someone can shed some light on how to address these. First, the strict order defined above is not quite a *total* order, since there are some pairs of distinct comments where one comment’s randomized score is equally likely to be higher or lower than the other. For example, all of the comments of the form , with an equal number of upvotes and downvotes, have this problem. This is probably not a big deal, though, since I think it is possible to *arbitrarily* order these comments, for example by increasing total number of votes.

But there are other more interesting pairs of incomparable comments. For example, consider and . The definition above is insufficient to rank these two… but it turns out that it had *better* be the case that , since we can find a *third* comment that lies between them:

This brings us to the next open question: is this order relation transitive (in other words, is it even a *partial* order)? I have been unable to prove this, only verify it computationally among comments with bounded numbers of votes.

The final problem is a more practical one: how efficiently can this order relation be *computed*? Evaluating the probability that one beta-distributed random variable exceeds another involves a double integral that “simplifies” to an expression involving factorials and a hypergeometric function of the numbers of upvotes and downvotes. If you want to experiment, following is Python code using the mpmath library to compute the probability :

from mpmath import fac, hyp3f2
def prob_greater(u1, d1, u2, d2):
return (hyp3f2(-d2, u2 + 1, u1 + u2 + 2, u2 + 2, u1 + u2 + d1 + 3, 1) *
fac(u1 + u2 + 1) / (fac(u1) * fac(u2)) *
fac(u1 + d1 + 1) * fac(u2 + d2 + 1) /
((u2 + 1) * fac(d2) * fac(u1 + u2 + d1 + 2)))
print(prob_greater(5, 0, 13, 1))

John Cook has written a couple of interesting papers on this, in the medical context of evaluating clinical trials. This one discusses various approximations, and this one presents exact formulas and recurrences for some special cases. The problem of computing the actual probability seems daunting… but perhaps it is a simpler problem in this case to not actually *compute* the value, but just determine whether it is greater than 1/2 or not?

In summary, I think these difficulties can be rolled up into the following more abstract statement of the problem: can we impose a “natural,” efficiently computable total order on the set of all beta distributions with positive integer parameters, that looks something like the order relation described above?