The answer to your headline question is **no**. A collection with `flatMap`

is not sufficient to be a monad. It *might* be a monad if it satisfies some further conditions.

Your "minor" issue certainly breaks the monadicity (the proper word for "monad-ness") of `Iterable`

. This is because many subtypes of `Iterable`

and `GenTraversableOnce`

are *not monads*. Therefore, `Iterable`

is not a monad.

Your "major" issue is not a problem at all. For example, the function argument to the `List`

monad's `flatMap`

receives the elements of the `List`

one at a time. Each element of the list generates a whole list of results, and those lists are all concatenated together at the end.

Fortunately, judging whether something is a monad is really easy! We just have to know the precise definition of *monad*.

### The requirements for being a monad

- A monad has to be a type constructor
`F[_]`

that takes one type argument. For example, `F`

could be `List`

, `Function0`

, `Option`

, etc.
- A monadic
*unit*. This is a function that takes a value of any type `A`

and produces a value of type `F[A]`

.
- A monadic
*composition* operation. It's an operation that takes a function of type `A => F[B]`

, and a function of type `B => F[C]`

and produces a composite function of type `A => F[C]`

.

(There are other ways of stating this, but I find this formulation straightforward to explain)

Consider these for `Iterable`

. It definitely takes one type argument. It has a unit of sorts in the function `Iterable(_)`

. And while its `flatMap`

operation doesn't strictly conform, we could certainly write:

```
def unit[A](a: A): Iterable[A] = Iterable(a)
def compose[A,B,C](f: A => Iterable[B],
g: B => Iterable[C]): A => Iterable[C] =
a => f(a).flatMap(g)
```

But this does not make it a monad, since a monad additionally has to satisfy certain *laws*:

- Associativity:
`compose(compose(f, g), h)`

= `compose(f, compose(g, h))`

- Identity:
`compose(unit, f)`

= `f`

= `compose(f, unit)`

An easy way to break these laws, as lmm has already pointed out, is to mix `Set`

and `List`

as the `Iterable`

in these expressions.

### "Semimonads"

While a type construction with just `flatMap`

(and not `unit`

), is not a monad, it may form what's called a *Kleisli semigroupoid*. The requirements are the same as for *monad*, except without the `unit`

operation and without the identity law.

(A note on terminology: A monad forms a *Kleisli category*, and a *semigroupoid* is a category without identities.)

### For-comprehensions

Scala's for-comprehensions technically have even *fewer* requirements than semigroupoids (just `map`

and `flatMap`

operations obeying *no* laws). But using them with things that are not at least semigroupoids has very strange and surprising effects. For example, it means that you can't inline definitions in a for-comprehension. If you had

```
val p = for {
x <- foo
y <- bar
} yield x + y
```

And the definition of `foo`

were

```
val foo = for {
a <- baz
b <- qux
} yield a * b
```

Unless the associativity law holds, we *cannot* rely on being able to rewrite this as:

```
val p = for {
a <- baz
b <- qux
y <- bar
} yield a * b + y
```

Not being able to do this kind of substitution is extremely counterintuitive. So most of the time when we work with for-comprehensions we assume that we're working in a monad (likely even if we're not aware of this), or at least a Kleisli semigroupoid.

But note that *this kind of substitution does not work in general for *`Iterable`

:

```
scala> val bar: Iterable[Int] = List(1,2,3)
bar: Iterable[Int] = List(1, 2, 3)
scala> val baz: Iterable[Int] = Set(1,2,3)
baz: Iterable[Int] = Set(1, 2, 3)
scala> val qux: Iterable[Int] = List(1,1)
qux: Iterable[Int] = List(1, 1)
scala> val foo = for {
| x <- bar
| y <- baz
| } yield x * y
foo: Iterable[Int] = List(1, 2, 3, 2, 4, 6, 3, 6, 9)
scala> for {
| x <- foo
| y <- qux
| } yield x + y
res0: Iterable[Int] = List(2, 2, 3, 3, 4, 4, 3, 3, 5, 5, 7, 7, 4, 4, 7, 7, 10, 10)
scala> for {
| x <- bar
| y <- baz
| z <- qux
| } yield x * y + z
res1: Iterable[Int] = List(2, 3, 4, 3, 5, 7, 4, 7, 10)
```

### For more information about monads

For more on monads in Scala, including what it all *means* and why we should care, I encourage you to have a look at chapter 11 of my book.

`def flatMap[B, That](f: (A) ⇒ GenTraversableOnce[B])(implicit bf: CanBuildFrom[Iterable[A], B, That]): That`

see: github.com/scala/scala/blob/2.11.x/src/library/scala/collection/… – stew Jan 3 '15 at 4:02