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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 {
       case e: PatternSyntaxException => None

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

share|improve this question
up vote 103 down vote accepted

TL;DR go directly to the final example

I'll try and recap


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.


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]


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

  //converts each character of the string to its corresponding code
  val f: String => List[Int] = s => 

  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 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])

    for {
      bound <- list
      out <- f(bound)
    } yield out
    //is the same as 
    list flatMap f
  2. the yield expression is converted to a concluding map call with the expression passed as argument

    for {
      bound <- list
    } yield f(bound)
    //is the same as
    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]

share|improve this answer
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
I don't understand what you mean by "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." Why would you do that? The nature of map is A => A so that wouldn't happen, right? – melston Apr 5 '15 at 14:35
@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 mapwill 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

share|improve this answer
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

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 .

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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

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