Rik de Kort writes:
This morning I stumbled across a very interesting blog post, dissecting some drama related to a non-replicating paper in computer science land. The question the paper tries to answer is whether some programming languages are more error prone than others. For a paper in computer science I would expect all their data and code to be open to begin with, but it wasn’t! As it turns out, once people got their hands on the data and code, they found severe flaws and wrote a rebuttal paper. And then there was a rebuttal rebuttal, etc.
I think this story is worth sharing for the following reasons:
– It’s a very recognizable example outside of social sciences.
– There is some indication the conclusions might be true even if the methodology to reach them was totally flawed.
It’s interesting. One thing, though. The linked post, by Hillel Wayne, starts off:
I love science. Not the “space is beautiful” faux-science, but the process of doing science. Hours spent calibrating equipment, cross-checking cites of cites of cites, tedious arguments about p-values and prediction intervals, all the stuff that makes science Go.
“Tedious arguments about p-values . . .”: sure, that can be part of the process of doing science, but it doesn’t have to be! There’s a whole world of serious science where the statistics goes straight to the scientific questions, and you don’t have to argue about p-values at all. Just for example see here or here or a zillion other applied papers here. I’m not saying you can’t do good science using p-values, nor am I saying that arguing about p-values can’t be a part of good science, nor am I trying to argue with Wayne’s personal experience doing science—I’m just saying it doesn’t have to be that way. As Don Rubin liked to say, one aspect of a good statistical method is that it allows you to spend less time talking about the statistics and more time talking about the science.
That linked post features this definition: “The P-value is the probability that you would have seen the same result if the hypothesis wasn’t true, purely due to other factors.” This is wrong. That’s fine. The author of the post is not a statistician. If I tried to describe some computer science term in my own words, without cheating and looking it up first, I’d probably get it wrong too. But I think this does add support to my idea that scientists and engineers have better things to do than argue about p-values. Sometimes it seems that the only thing more common than a practitioner misunderstanding a p-value is someone misunderstanding p-values in the process of trying to explain them to others! Later he describes the p-value as “the probability that a ‘coincidence’ could explain the data.” That’s wrong. It’s true that the p-value is a probability, and it does have something to do with coincidences, and it also has something to do with data, but that’s about it.
Also, Wayne writes:
Don’t trust anything that’s not replicated.
If an effect exists, it should be observable by anyone in similar conditions. This is one of the core foundations of empirical science: all claims should be replicated by a third party. If something doesn’t replicate, then the effect is more limited than we expected, or there was an implicit assumption in the original experiment, or somebody made a mistake somewhere.
Sometimes. Not always. There are observational sciences such as political science and economics, where you can’t just run 10 more elections or start 10 more civil wars in order to get new data. I mean, sure, maybe the appropriate response to this is to not trust economics or political science, and maybe that’s right—but that just pushes things back one step, and we have to decide how to make decisions and understand the world given science that can’t be trusted.
And one other thing. Near the end of the post is the following advice:
Be diligent with your threats to validity. Check all of your assumptions. Don’t blindly trust automation. Don’t dox other scientists. The usual.
I agree with most of this. But what’s with “Don’t dox other scientists”? First off, if doxing is a bad idea, we shouldn’t dox anyone, right? But was there any doxing involved? I scrolled through the post and found that someone linked to someone else’s Facebook account. I’m not on Facebook so I’m not at all sure about this, but isn’t a Facebook account public? I’m confused about how it is doxing to link to that. I do agree that it’s better to keep science discussions scientific rather than personal; I just feel like I’ve lost the thread somewhere along the line regarding the doxing.
But let me conclude with a point that really resonates with me.
Wayne writes:
Is this even a good idea?
We’ve just spent several thousand words on methodology to show how the original FSE paper was flawed. But was that all really necessary? Most people point to a much bigger issue: the entire idea of measuring a language’s defect rate via GitHub commits just doesn’t make any sense. How the heck do you go from “these people have more DFCs” to “this language is more buggy”? I saw this complaint raised a lot, and if we just stop there I could have skipped rereading all the papers a dozen times over.
Jan Vitek emphasizes this in his talk: if they just said “the premise is nonsense”, nobody would have listened to them. It’s only by showing that the FSE authors messed up methodologically that TOPLAS could establish “sufficient cred” to attack the premise itself. The FSE authors put in a lot of effort into their paper. Responding to that all is “nuh-uh your premise is nonsense” is bad form, even if the premise is nonsense. Who is more trustworthy: the people who spent years getting their paper through peer review, or a random internet commenter who probably stopped at the abstract?
It all comes back to science as a social enterprise. We use markers of trust and integrity as heuristics on whether or not to devote time to understanding the claim itself. This is the same reason people are more likely to listen to a claim coming from a respected scientist than from a crackpot. Pointing out a potential threat to validity isn’t nearly as powerful as showing how that threat actually undermines the paper, and that’s what TOPLAS had to do to be taken seriously.
Setting aside all the technical details here, which I’m not in any position to evaluate, I think Wayne is on to something here, and it reminds me of the asymmetries between publishing new ideas and publishing criticisms, which we’ve discussed here, here, and here, among other places. That last article has the title, “It’s too hard to publish criticisms and obtain data for replication,” which pretty much says it all.
It’s indeed frustrating to see bad work, work that’s clearly bad, and to feel that the only way to criticize it is to first put in a ton of effort to figure out exactly what went wrong.
It’s like if someone was trying to sell you a perpetual motion machine and the only way you could get him off your doorstep is to figure out exactly where’s the connection to the hidden power supply, and then once you did that, other people jumped out of the bushes to say that it’s a really good perpetual motion machine and the people who created it are promising scholars and why are you being so picky what is it you don’t want to save the world with free power etc etc. Enough to make you want to drift into stream of consciousness, at the very least.
P.S. The post concludes with this:
I shared a first draft of this essay on my newsletter, all the way back in November. It’s pretty much the same content as my blog except weekly instead of monthly. So if you like my writing, why not subscribe?
That makes me think that I could charge people money to read my blog posts 6 months ahead of time . . .
