Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Confused with the for-comprehension to flatMap/Map transformation

I really don't seem to be understanding Map and FlatMap. What I am failing to understand is how a for-comprehension is a sequence of nested calls to map and flatMap. The following example is from Functional Programming in Scala

``````def bothMatch(pat:String,pat2:String,s:String):Option[Boolean] = for {
f <- mkMatcher(pat)
g <- mkMatcher(pat2)
} yield f(s) && g(s)
``````

translates to

``````def bothMatch(pat:String,pat2:String,s:String):Option[Boolean] =
mkMatcher(pat) flatMap (f =>
mkMatcher(pat2) map (g => f(s) && g(s)))
``````

The mkMatcher method is defined as follows:

``````  def mkMatcher(pat:String):Option[String => Boolean] =
pattern(pat) map (p => (s:String) => p.matcher(s).matches)
``````

And the pattern method is as follows:

``````import java.util.regex._

def pattern(s:String):Option[Pattern] =
try {
Some(Pattern.compile(s))
}catch{
case e: PatternSyntaxException => None
}
``````

It will be great if someone could shed some light on the rationale behind using map and flatMap here.

-

TL;DR go directly to the final example

I'll try and recap

Definitions

The `for` comprehension is a syntax shortcut to combine `flatMap` and `map` in a way that's easy to read and reason about.

Let's simplify things a bit and assume that every `class` that provides both aforementioned methods can be called a `monad` and we'll use the symbol `M[A]` to mean a `monad` with an inner type `A`.

Examples

Some commonly seen monads

• `List[String]` where
• `M[_]: List[_]`
• `A: String`
• `Option[Int]` where
• `M[_]: Option[_]`
• `A: Int`
• `Future[String => Boolean]` where
• `M[_]: Future[_]`
• `A: String => Boolean`

map and flatMap

Defined in a generic monad `M[A]`

`````` /* applies a transformation of the monad "content" mantaining the
* monad "external shape"
* i.e. a List remains a List and an Option remains an Option
* but the inner type changes
*/
def map(f: A => B): M[B]

/* applies a transformation of the monad "content" by composing
* this monad with an operation resulting in another monad instance
* of the same type
*/
def flatMap(f: A => M[B]): M[B]
``````

e.g.

``````  val list = List("neo", "smith", "trinity")

//converts each character of the string to its corresponding code
val f: String => List[Int] = s => s.map(_.toInt).toList

list map f
>> List(List(110, 101, 111), List(115, 109, 105, 116, 104), List(116, 114, 105, 110, 105, 116, 121))

list flatMap f
>> List(110, 101, 111, 115, 109, 105, 116, 104, 116, 114, 105, 110, 105, 116, 121)
``````

for expression

1. Each line in the expression using the `<-` symbol is translated to a `flatMap` call, except for the last line which is translated to a concluding `map` call, where the "bound symbol" on the left-hand side is passed as the parameter to the argument function (what we previously called `f: A => M[B]`):

``````// The following ...
for {
bound <- list
out <- f(bound)
} yield out

// ... is translated by the Scala compiler as ...
list.flatMap { bound =>
f(bound).map { out =>
out
}
}

// ... which can be simplified as ...
list.flatMap { bound =>
f(bound)
}

// ... which is just another way of writing:
list flatMap f
``````
2. A for-expression with only one `<-` is converted to a `map` call with the expression passed as argument:

``````// The following ...
for {
bound <- list
} yield f(bound)

// ... is translated by the Scala compiler as ...
list.map { bound =>
f(bound)
}

// ... which is just another way of writing:
list map f
``````

Now to the point

As you can see, the `map` operation preserves the "shape" of the original `monad`, so the same happens for the `yield` expression: a `List` remains a `List` with the content transformed by the operation in the `yield`

On the other hand each binding line in the `for` is just a composition of successive `monads`, which must be "flattened" in order to maintain a single "external shape"

Suppose for a moment that each internal binding was translated to a `map` call, but the right-hand was the same `A => M[B]` function, you would end up with a `M[M[B]]` for each line in the comprehension.
The intent of the whole `for` syntax is to easily "flatten" the concatenation of successive monadic operations (i.e. operations that "lift" a value in a "monadic shape": `A => M[B]`), with the addition of a final `map` operation that possibly performs a concluding transformation

I hope this explains the logic behind the choice of translation, which is applied in a mechanical way, that is: `n` `flatMap` nested calls concluded by a single `map` call.

A contrived illustrative example
Meant to show the expressiveness of the `for` syntax

``````case class Customer(value: Int)
case class Consultant(portfolio: List[Customer])
case class Branch(consultants: List[Consultant])
case class Company(branches: List[Branch])

def getCompanyValue(company: Company): Int = {

val valuesList = for {
branch     <- company.branches
consultant <- branch.consultants
customer   <- consultant.portfolio
} yield (customer.value)

valueList reduce (_ + _)
}
``````

Can you guess the type of `valuesList`?

As already said, the shape of the `monad` is mantained through the comprehension, so we start with a `List` in `company.branches`, and must end with a `List`.
The inner type instead changes and is determined by the `yield` expression: which is `customer.value: Int`

`valueList` should be a `List[Int]`

-
Excellent lecture, and examples solidified my understanding. – Kevin Meredith Oct 5 '13 at 14:46
The words "is the same as" belong to the meta-language and should be moved out of the code block. – day Dec 14 '13 at 23:38
Every FP beginner should read this. How can this be achieved? – mert inan Jan 10 '14 at 23:37
@melston Let's make an example with `Lists`. If you `map` twice a function `A => List[B]` (which is one of the essential monadic operation) over some value, you end up with a List[List[B]] (we're taking for granted that the types match). The for comprehension inner loop composes those functions with the corresponding `flatMap` operation, "flattening" the List[List[B]] shape into a simple List[B]... I hope this is clear – pagoda_5b Apr 6 '15 at 22:25
@coolbreeze It could be that I didn't express it clearly. What I meant is that the `yield` clause is `customer.value`, whose type is `Int`, therefore the whole `for comprehension` evaluates to a `List[Int]`. – pagoda_5b Dec 17 '15 at 20:23

The rationale is to chain monadic operations which provides as a benefit, proper "fail fast" error handling.

It is actually pretty simple. The `mkMatcher` method returns an `Option` (which is a Monad). The result of `mkMatcher`, the monadic operation, is either a `None` or a `Some(x)`.

Applying the `map` or `flatMap` function to a `None` always returns a `None` - the function passed as a parameter to `map` and `flatMap` is not evaluated.

Hence in your example, if `mkMatcher(pat)` returns a None, the flatMap applied to it will return a `None` (the second monadic operation `mkMatcher(pat2)` will not be executed) and the final `map`will again return a `None`. In other words, if any of the operations in the for comprehension, returns a None, you have a fail fast behavior and the rest of the operations are not executed.

This is the monadic style of error handling. The imperative style uses exceptions, which are basically jumps (to a catch clause)

A final note: the `patterns` function is a typical way of "translating" an imperative style error handling (`try`...`catch`) to a monadic style error handling using `Option`

-
Do you know why `flatMap` (and not `map`) is used to "concatenate" the first and the second invocation of `mkMatcher`, but why `map` (and not `flatMap`) is used "concatenate" the second `mkMatcher` and the `yields` block? – Malte Schwerhoff Jan 30 '13 at 8:45
`flatMap` expects you to pass a function returning the result "wrapped"/lifted in the Monad, while `map` will do the wrapping/lifting itself. During call chaining of operations in the `for comprehension` you need to `flatmap` so that the functions passed as parameter are able to return `None` (you cannot lift the value into a None). The last operation call, the one in the `yield` is expected to run and return a value; a `map` to chain that last operation is sufficient and avoids having to lift the result of the function into the monad. – Bruno Grieder Jan 30 '13 at 13:01

This can be traslated as:

``````def bothMatch(pat:String,pat2:String,s:String):Option[Boolean] = for {
f <- mkMatcher(pat)  // for every element from this [list, array,tuple]
g <- mkMatcher(pat2) // iterate through every iteration of pat
} yield f(s) && g(s)
``````

Run this for a better view of how its expanded

``````def match items(pat:List[Int] ,pat2:List[Char]):Unit = for {
f <- pat
g <- pat2
} println(f +"->"+g)

bothMatch( (1 to 9).toList, ('a' to 'i').toList)
``````

results are:

``````1 -> a
1 -> b
1 -> c
...
2 -> a
2 -> b
...
``````

This is similar to `flatMap` - loop through each element in `pat` and foreach element `map` it to each element in `pat2`

-

First, `mkMatcher` returns a function whose signature is `String => Boolean`, that's a regular java procedure which just run `Pattern.compile(string)`, as shown in the `pattern` function. Then, look at this line

``````pattern(pat) map (p => (s:String) => p.matcher(s).matches)
``````

The `map` function is applied to the result of `pattern`, which is `Option[Pattern]`, so the `p` in `p => xxx` is just the pattern you compiled. So, given a pattern `p`, a new function is constructed, which takes a String `s`, and check if `s` matches the pattern.

``````(s: String) => p.matcher(s).matches
``````

Note, the `p` variable is bounded to the compiled pattern. Now, it's clear that how a function with signature `String => Boolean` is constructed by `mkMatcher`.

Next, let's checkout the `bothMatch` function, which is based on `mkMatcher`. To show how `bothMathch` works, we first look at this part:

``````mkMatcher(pat2) map (g => f(s) && g(s))
``````

Since we got a function with signature `String => Boolean` from `mkMatcher`, which is `g` in this context, `g(s)` is equivalent to `Pattern.compile(pat2).macher(s).matches`, which returns if the String s matches pattern `pat2`. So how about `f(s)`, it's same as `g(s)`, the only difference is that, the first call of `mkMatcher` uses `flatMap`, instead of `map`, Why? Because `mkMatcher(pat2) map (g => ....)` returns `Option[Boolean]`, you will get a nested result `Option[Option[Boolean]]` if you use `map` for both call, that's not what you want .

-