Exercises
The following exercises are designed to test your knowledge of the Scala programming language. They cover the content presented in this chapter, along with some additional Scala features. The last two exercises contrast the difference between concurrent and distributed programming, as defined in this chapter. You should solve them by sketching out a pseudocode solution, rather than a complete Scala program.
- Implement a
compose
 method with the following signature:def compose[A, B, C] (g: B => C, f: A => B): A => C = ???
This method must return a function
h
, which is the composition of the functionsf
andg
- Implement a
fuse
method with the following signature:def fuse[A, B] (a: Option[A], b: Option[B]): Option[(A, B)] = ???
The resulting
Option
object should contain a tuple of values from theOption
objectsa
andb
, given that botha
andb
are non-empty. Use for-comprehensions - Implement a
check
method, which takes a set of values of typeT
and a function of typeT => Boolean
:def check[T](xs: Seq[T])(pred: T => Boolean): Boolean = ???
The method must return
true
if and only if thepred
function returnstrue
for all the values inxs
without throwing an exception. Use thecheck
method as follows:check(0 until 10)(40 / _ > 0)
Tip
The
check
method has a curried definition: instead of just one parameter list, it has two of them. Curried definitions allow a nicer syntax when calling the function, but are otherwise semantically equivalent to single-parameter list definitions. - Modify the
Pair
class from this chapter so that it can be used in a pattern match.Tip
If you haven't already done so, familiarize yourself with pattern matching in Scala.
- Implement a
permutations
function, which, given a string, returns a sequence of strings that are lexicographic permutations of the input string:def permutations(x: String): Seq[String]
- Implement a
combinations
function that, given a sequence of elements, produces an iterator over all possible combinations of lengthn
. A combination is a way of selecting elements from the collection so that every element is selected once, and the order of elements does not matter. For example, given a collectionSeq(1, 4, 9, 16)
, combinations of length 2 areSeq(1, 4)
,Seq(1, 9)
,Seq(1, 16)
,Seq(4, 9)
,Seq(4, 16)
, andSeq(9, 16)
. The combinations function has the following signature:def combinations(n: Int, xs: Seq[Int]): Iterator[Seq[Int]]
See the
Iterator
API in the standard library documentation - Implement a method that takes a regular expression, and returns a partial function from a string to lists of matches within that string:
def matcher (regex: String): PartialFunction[String, List[String]]
The partial function should not be defined if there are no matches within the argument strings. Otherwise, it should use the regular expression to output the list of matches.
- Consider that you and three of your colleagues working in an office divided into cubicles. You cannot see each other, and you are not allowed to verbally communicate, as that might disturb other workers. Instead, you can throw pieces of paper with short messages at each other. Since you are confined in a cubicle, neither of you can tell if the message has reached its destination. At any point, you or one of your colleagues may be called to the boss's office and kept there indefinitely. Design an algorithm in which you and your colleagues can decide when to meet at the local bar. With the exception of the one among you who was called to the boss's office, all of you have to decide on the same time. What if some of the paper pieces can arbitrarily miss the target cubicle?
- Imagine that, in the previous exercise, you and your colleagues also have a whiteboard in the hall next to the office. Each one of you can occasionally pass through the hall and write something on the whiteboard, but there is no guarantee that either of you will be in the hall at the same time.
Solve the problem from the previous exercise, this time using the whiteboard.