Scala: how to understand the flatMap method of Try?

The flatMap method of the Success is implemented like this:

``````  def flatMap[U](f: T => Try[U]): Try[U] =
try f(value)
catch {
case NonFatal(e) => Failure(e)
}
``````

I kinda understand what this method is doing, it helps us to avoid writing a lot of catching code.

But in what sense is it similar to the regular flatMap?

A regular flatMap takes a sequence of sequences, and put all the elements into one big "flat" sequence.

But the flatMap method of Try is not really flattening anything.

So, how to understand the flatMap method of Try?

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Search for monads/monoids pattern. flatMap transform original A[T] to A[U]. Option, Try, Future it do not need to be converted/flatten. See very old document about monads – Andrzej Jozwik Nov 25 '13 at 14:35
The methods `map` and `flatMap` are not about sequences, they are about monads. There are many monads that have nothing to do with collections of any sort. `Try` and `Future` are examples of these. (While `Try` is not technically, strictly a monad, it's close enough for most purposes.) – Randall Schulz Nov 25 '13 at 14:45
However, my understanding is that flatMap is called that because of the flattening it does do on sequences. So at a minimum there's some cognitive dissonance when applying it to non-collection monads. It's reasonable to ask for an explanation and an answer other than "it's not soup, sir, it's broth" would be good (c.f foreach, which has the same dissonance). – The Archetypal Paul Nov 25 '13 at 15:10
@Paul: the flattening metaphor also fits the stricter Monad definition of wrapping computations: it transforms a nested structure of transformations into a flat one. You could substitute it for 'unwrapping' without much loss of significance as well. – danielkza Nov 25 '13 at 15:55
And how about 'foreach'? :) Seriously, that's the kind of explanation that helps. Thanks. – The Archetypal Paul Nov 25 '13 at 16:55

Without entering into monads, instead of thinking about it in terms of collections, you could think of it in terms of structures (where a collection becomes a structure with many entries).

Now, take a look at the signature of `Try.flatmap` (from your post):

`def flatMap[U](f: T => Try[U]): Try[U]` the function `f` transforms T into a Try[U] in the context of Try[T].

In contrast, imagine the operation were 'map', the result would be:

`def badMap[U](f: T => Try[U]): Try[Try[U]]`

As you can see, flatmap is 'flattening' the result into the context of Try[T] and producing `Try[U]` instead of the nested `Try[Try[U]]`.

You can apply the same 'flattening of nested structure' concept to collections as you mention.

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I was already afraid the accepted answer would be some complex monad theory, but instead it was the simple and clear one I immediately thought of! – Erik Allik Jan 30 '14 at 12:37

You may consider Try[T] as similar to a collection of only one element (like Option[T]) .

When the "sequence of sequences" is "only one sequence", map and flatmap are almost similar. Only difference being the signature of the function.

No flattening is required in this case.

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same in case of map? – Shyamendra Solanki Nov 25 '13 at 15:28
@Solanki yep, I was wrong – om-nom-nom Nov 25 '13 at 15:34

I found Dan Spiewak's "Monads Are Not Metaphors" very helpful in getting my head around monads. For folks starting from Scala (like me) it's far easier to grasp than anything else I've found - including Odersky's writings. In reading it, note that 'bind'=='flatMap'.

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As you can read in A Tour of Scala: Sequence Comprehensions: "In scala every datatype that supports the operations filter, map, and flatMap (with the proper types) can be used in sequence comprehensions." In fact this means you can threat it like a monad.
And flatMap for monad have signature like this:

``````def flatMap(f: A => M[B]): M[B]
``````

All collections in scala have monadic interfaces, so you can look at monadic operations in that narrow scope as operations on sequences. But that is not the whole story. In case of some monads looking on them as on collections is more confusing than helpful. Generally flatMap applies a transformation of the monad "content" by composing this monad with an operation resulting in another monad instance of the same type. So you can look at monads in at least two ways:

• Monad is some kind of collection (or box holding something) and elements of that collection are "content".
• Monad is some kind of context and elements of monad are just some computations made in that context.

Sometimes it's easier to think about monad as collection, sometimes it's easier to think about it as context. At least for me. In fact that both approaches are interchangeable, i.e. you can look at lists (collections) as nondeterministic computations which may return an arbitrary number of results.

So in case of Try it could be easier to think about it as execution context, with two states, Success and Failure. If you want to compose few Tries then and one of them is in Failure state then whole context becomes Failure (chain is broken). Otherwise you can do some operations on the "content" of that Tries and the context is Success.

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A regular flatMap takes a sequence of sequences, and put all the elements into one big "flat" sequence.

Slight correction:

A regular `flatMap` takes a sequence (more generally monad) , has an argument which is a function converting an element into a sequence (monad), and returns a "flat" sequence (monad).

For comparison purposes, the gory substeps mentioned here :). The `flatmap` method iterates over input sequence invoking `f(element)`, but creates a singular new result sequence. The "flatten" part is applied after each function argument application, `f(element)` - it does a nested iteration over the resulting sub-sequence, yielding each entry in the singular result sequence.

The equivalent for `Success`, with a `value` inside (more generally a monad):

• `flatmap` has an argument which is a function converting `Success` into `Try` = `Success(value)` OR `Failure(exception)`. After `f(value)` is applied, the result is already a `Try`. The "flatten" part is a trivial/null operation: iterating over this function result would give just one entry, hence `Try`/`Success`/`Failure` don't even need to implement `Iterable`). Doesn't wrap additional layers of `Success`/`Failure`, and so returns a "flat" `Try`.

I.e. The "flat" part means it doesn't cascade `Success`/`Failure` wrappers, just as a sequence's `flatmap` doesn't cascade sequences in a (value tree) hierarchy.

• this is different to `map`, whose argument is a function converting `Success` into an arbitrary type `U`; after `f(value)` is applied, map must add an additional layer of new `Success`/`Failure` wrapping around the `value`/`exception`.

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A regular flatMap takes a sequence of sequences, and put all the elements into one big "flat" sequence

It would be fair to replace word sequence to monad here, because this operation doesn't relate only to collection, actually collections are also monads. Think of `Try` as collection that can contain either `Success` value of `Failure`

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This hardly explains anything to person who have no notion of monad. – om-nom-nom Nov 25 '13 at 14:58
A good presentation for understanding monads typeclassopedia.bitbucket.org – maks Nov 25 '13 at 16:07