*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
`Option[Int]`

where
`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**

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]`

)

```
//writing
for {
bound <- list
out <- f(bound)
} yield out
//is the same as
list flatMap f
```

the `yield`

expression is converted to a concluding `map`

call with the expression passed as argument

```
//writing
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]`