When you pass `(+)`

in to the first argument of `foldr`

you implicitly declare that `a`

is the same as `b`

. This gets confusing since we tend to reuse names, but if I write it all together using the same namespace for the type variables

```
(+) :: Num i => i -> i -> i
foldr :: (a -> b -> b) -> b -> [a] -> b
foldr (+) :: Num i => i -> [i] -> i
```

where the third line implies that `i ~ a`

and `i ~ b`

thus, by transitivity, `a ~ b`

. Also, it might be more clear here to see that the first remaining parameter in `foldr (+)`

is an "initial" value for the fold and the `[i]`

bit is the list that we're compressing, folding, reducing.

It might be even more clear to call `foldr (+) 0`

by it's more common name, `sum :: Num a => [a] -> a`

. We also have `foldr (*) 1`

as `product :: Num a => a -> [a]`

.

So yes, your description of how the accumulator function is behaving in `foldr (+)`

is exactly correct, but more specific than the function is in general. For instance, we can use `foldr`

to build a `Map`

.

```
foldr (\(k, v) m -> Map.insert m k v) Map.empty :: Ord k => [(k, v)] -> Map k v
```

In this case the accumulator function takes our association list and keeps inserting the values into our accumulat*ing* `Map`

, which begins empty. To be utterly thorough here, let me write out the types all together again

```
(\(k, v) -> m -> Map.insert m k v) :: Ord k => (k, v) -> Map k v -> Map k v
foldr :: (a -> b -> b) -> b -> [a] -> b
foldr (\(k, v) -> m -> Map.insert m k v) :: Ord k => Map k v -> [(k, v)] -> Map k v
```

where we've forced `a ~ (k, v)`

and `b ~ Map k v`

.

As a final view on the matter, here's the definition of foldr with some suggestive variable names

```
foldr _ b [] = b
foldr (<>) b (a:as) = a <> foldr f b as
```

So you can see how `(<>) :: a -> b -> b`

combines `a`

and `b`

types. We can "run" this definition explicitly to see how it builds up the computation.

```
foldr (+) 0 [1,2,3]
1 + (foldr (+) 0 [2,3])
1 + (2 + (foldr (+) 0 [3]))
1 + (2 + (3 + (foldr (+) 0 [])))
1 + (2 + (3 + 0))
1 + (2 + 3)
1 + 5
6
```

Which may be even more clear when we use a non-symmetric operation like the `Map`

example above. Below I'm using `{{ k -> v, k -> v }}`

to represent the `Map`

since it isn't printable directly.

```
-- inserts a single (k,v) pair into a Map
ins :: Ord k => (k, v) -> Map k v -> Map k v
ins (k, v) m = Map.insert m k v
foldr ins Map.empty [('a', 1), ('b', 2)]
ins ('a', 1) (foldr ins Map.empty [('b', 2)])
ins ('a', 1) (ins ('b', 2) (foldr ins Map.empty []))
ins ('a', 1) (ins ('b', 2) Map.empty)
ins ('a', 1) (ins ('b', 2) {{ }})
ins ('a', 1) {{ 'b' -> 2 }}
{{ 'b' -> 2, 'a' -> 1 }}
```