For anyone reading this at a later date I think the following should be helpful.

A small library is available here https://clojars.org/beoliver/map-inversions

Inverting a map may return a relation. If the map is injective (one-to-one) then the inverse will also be one-to-one. If the map (as if often the case) is many-to-one then you should use a set or vector.

#Values treated as atomic
##one-to-one
the values of the map are unique

```
(defn invert-one-to-one
"returns a one-to-one mapping"
[m]
(persistent! (reduce (fn [m [k v]] (assoc! m v k)) (transient {}) m)))
(def one-to-one {:a 1 :b 2 :c 3})
> (invert-one-to-one one-to-one)
{1 :a 2 :b 3 :c}
```

##many-to-one
The values of the map are **not** unique. This is very common - and it is safest to assume that your maps are of this form... so `(def invert invert-many-to-one)`

```
(defn invert-many-to-one
"returns a one-to-many mapping"
([m] (invert-many-to-one #{} m))
([to m]
(persistent!
(reduce (fn [m [k v]]
(assoc! m v (conj (get m v to) k)))
(transient {}) m))))
(def many-to-one {:a 1 :b 1 :c 2})
> (invert-many-to-one many-to-one)
{1 #{:b :a}, 2 #{:c}} ; as expected
> (invert-many-to-one [] many-to-one)
{1 [:b :a], 2 [:c]} ; we can also use vectors
> (invert-one-to-one many-to-one) ; what happens when we use the 'wrong' function?
{1 :b, 2 :c} ; we have lost information
```

#Values treated as collections
##one-to-many
values are sets/collections but their intersections are always empty.
(No element occurs in two different sets)

```
(defn invert-one-to-many
"returns a many-to-one mapping"
[m]
(persistent!
(reduce (fn [m [k vs]] (reduce (fn [m v] (assoc! m v k)) m vs))
(transient {}) m)))
(def one-to-many (invert-many-to-one many-to-one))
> one-to-many
{1 #{:b :a}, 2 #{:c}}
> (invert-one-to-many one-to-many)
{:b 1, :a 1, :c 2} ; notice that we don't need to return sets as vals
```

##many-to-many
values are sets/collections and there exists at least two values whose intersection is not empty. If your values are collections then it is best to assume that they fall into this category.

```
(defn invert-many-to-many
"returns a many-to-many mapping"
([m] (invert-many-to-many #{} m))
([to m]
(persistent!
(reduce (fn [m [k vs]]
(reduce (fn [m v] (assoc! m v (conj (get m v to) k))) m vs))
(transient {}) m))))
(def many-to-many {:a #{1 2} :b #{1 3} :c #{3 4}})
> (invert-many-to-many many-to-many)
{1 #{:b :a}, 2 #{:a}, 3 #{:c :b}, 4 #{:c}}
;; notice that there are no duplicates when we use a vector
;; this is because each key appears only once
> (invert-many-to-many [] many-to-many)
{1 [:a :b], 2 [:a], 3 [:b :c], 4 [:c]}
> (invert-many-to-one many-to-many)
{#{1 2} #{:a}, #{1 3} #{:b}, #{4 3} #{:c}}
> (invert-one-to-many many-to-many)
{1 :b, 2 :a, 3 :c, 4 :c}
> (invert-one-to-one many-to-many)
{#{1 2} :a, #{1 3} :b, #{4 3} :c} ; this would be missing information if we had another key :d mapping to say #{1 2}
```

You could also use `invert-many-to-many`

on the `one-to-many`

example.

`{:a 1 :b 1}`

. If you want to preserve information thensetsof keys should become values:`{1 #{:a :b}}`

.