# Hindley Milner Type Inference in F#

Can somebody explain step by step type inference in following F# program:

``````let rec sumList lst =
match lst with
| [] -> 0
| hd :: tl -> hd + sumList tl
``````

I specifically want to see step by step how process of unification in Hindley Milner works.

• I think this might belong in another SE site, but not sure which :) Dec 6 '11 at 7:58
• If it is can you give me a link to that? It would be helpful. Dec 6 '11 at 8:01
• Well, I'd think it belongs to Theo CS, but I don't think they'd welcome it. Unless a smart moderator comes along, I guess this'll just remain here :) Dec 6 '11 at 8:06
• I did not get it. Could you find that link? Dec 6 '11 at 8:35
• This isn't exactly a technical question about programming, so it might not fit StackOverflow. I had suggested this site: cstheory.stackexchange.com, but I'm not sure it'll fit there, too. Dec 6 '11 at 8:48

Fun stuff!

First we invent a generic type for sumList: `x -> y`

And get the simple equations: `t(lst) = x`; `t(match ...) = y`

Now you add the equation: `t(lst) = [a]` because of `(match lst with [] ...)`

Then the equation: `b = t(0) = Int`; `y = b`

Since 0 is a possible result of the match: `c = t(match lst with ...) = b`

From the second pattern: `t(lst) = [d]`; `t(hd) = e`; `t(tl) = f`; `f = [e]`; `t(lst) = t(tl)`; `t(lst) = [t(hd)]`

Guess a type (a generic type) for `hd`: `g = t(hd)`; `e = g`

Then we need a type for `sumList`, so we'll just get a meaningless function type for now: `h -> i = t(sumList)`

So now we know: `h = f`; `t(sumList tl) = i`

Then from the addition we get: `Addable g`; `Addable i`; `g = i`; `t(hd + sumList tl) = g`

Now we can start unification:

`t(lst) = t(tl)` `=>` `[a] = f = [e]` `=>` `a = e`

`t(lst) = x = [a] = f = [e]`; `h = t(tl) = x`

`t(hd) = g = i` `/\` `i = y` `=>` `y = t(hd)`

`x = t(lst) = [t(hd)]` `/\` `t(hd) = y` `=>` `x = [y]`

`y = b = Int` `/\` `x = [y]` `=>` `x = [Int]` `=>` `t(sumList) = [Int] -> Int`

I skipped some trivial steps, but I think you can get how it works.

• Thanks :) had to read each line twice-thrice but now understood it. Thanks again. Dec 6 '11 at 8:10