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.