In order to do such a transformation, we need to use some identity the operations have. For example, as you wrote, `map`

has the identity

```
map f ∘ map g ≡ map (f ∘ g)
```

(where `∘`

stands for function composition - see Function1.compose(...); and `≡`

stands for an equivalence of expressions). This is because classes with `map`

can be viewed as functors, so any reasonable implementation of `map`

must preserve this property.

On the other hand, classes that have `flatMap`

and have a way how to create some kind of one-element instance (like creating a singleton `Set`

) usually form a monad. So we may try to deduce some transformations from the monad rules. But the only identity we can deduce for repeated applications of `flatMap`

is

```
(set flatMap f) flatMap g ≡ x flatMap { y => f(y) flatMap g }
```

which is a kind of associativity relationship for `flatMap`

composition. This doesn't help much for optimizing the computation (actually it can make it worse). So, the conclusion is, there is no similar general "optimizing" identity for `flatMap`

.

The bottom line is: Each function given to `Set.flatMap`

creates a new `Set`

for each element it's applied to. We cannot avoid creating such intermediate sets unless we completely forget using composing `flatMap`

and solve the problem in some different way. Usually this is not worth, since composing `flatMap`

s (or using `for(...) yield ..`

) is much cleaner and more readable, and the little speed trade-off isn't usually a big issue.