gaeljw/Anagrams.scala

## Anagrams.scala
package forcomp

import scala.collection.immutable._

object Anagrams {

  /** A word is simply a `String`. */
  type Word = String

  /** A sentence is a `List` of words. */
  type Sentence = List[Word]

  /** `Occurrences` is a `List` of pairs of characters and positive integers saying
    * how often the character appears.
    * This list is sorted alphabetically w.r.t. to the character in each pair.
    * All characters in the occurrence list are lowercase.
    *
    * Any list of pairs of lowercase characters and their frequency which is not sorted
    * is **not** an occurrence list.
    *
    * Note: If the frequency of some character is zero, then that character should not be
    * in the list.
    */
  type Occurrences = List[(Char, Int)]

  /** The dictionary is simply a sequence of words.
    * It is predefined and obtained as a sequence using the utility method `loadDictionary`.
    */
  val dictionary: List[Word] = loadDictionary

  /** Converts the word into its character occurrence list.
    *
    * Note: the uppercase and lowercase version of the character are treated as the
    * same character, and are represented as a lowercase character in the occurrence list.
    *
    * Note: you must use `groupBy` to implement this method!
    */
  def wordOccurrences(w: Word): Occurrences = w.toLowerCase.groupBy(c => c).map { case (c, l) => (c, l.length) }.toList.sortBy(_._1)

  /** Converts a sentence into its character occurrence list. */
  def sentenceOccurrences(s: Sentence): Occurrences = wordOccurrences(s.mkString)

  /** The `dictionaryByOccurrences` is a `Map` from different occurrences to a sequence of all
    * the words that have that occurrence count.
    * This map serves as an easy way to obtain all the anagrams of a word given its occurrence list.
    *
    * For example, the word "eat" has the following character occurrence list:
    *
    * `List(('a', 1), ('e', 1), ('t', 1))`
    *
    * Incidentally, so do the words "ate" and "tea".
    *
    * This means that the `dictionaryByOccurrences` map will contain an entry:
    *
    * List(('a', 1), ('e', 1), ('t', 1)) -> Seq("ate", "eat", "tea")
    *
    */
  lazy val dictionaryByOccurrences: Map[Occurrences, List[Word]] = dictionary.groupBy(w => wordOccurrences(w))

  /** Returns all the anagrams of a given word. */
  def wordAnagrams(word: Word): List[Word] = dictionaryByOccurrences.getOrElse(wordOccurrences(word), List())

  /** Returns the list of all subsets of the occurrence list.
    * This includes the occurrence itself, i.e. `List(('k', 1), ('o', 1))`
    * is a subset of `List(('k', 1), ('o', 1))`.
    * It also include the empty subset `List()`.
    *
    * Example: the subsets of the occurrence list `List(('a', 2), ('b', 2))` are:
    *
    * List(
    * List(),
    * List(('a', 1)),
    * List(('a', 2)),
    * List(('b', 1)),
    * List(('a', 1), ('b', 1)),
    * List(('a', 2), ('b', 1)),
    * List(('b', 2)),
    * List(('a', 1), ('b', 2)),
    * List(('a', 2), ('b', 2))
    * )
    *
    * Note that the order of the occurrence list subsets does not matter -- the subsets
    * in the example above could have been displayed in some other order.
    */
  def combinations(occurrences: Occurrences): List[Occurrences] = occurrences match {
    case Nil => List(List())
    case (c, n) :: xs =>
      val subComb = combinations(xs)
      val curComb = (1 to n).map(i => (c, i))
      val mixComb = (for {
        charOcc <- curComb
        o <- subComb
      } yield charOcc :: o).toList
      // Looks bad but works...
      mixComb ++ subComb ++ curComb.map(o => List(o))
  }

  /** Subtracts occurrence list `y` from occurrence list `x`.
    *
    * The precondition is that the occurrence list `y` is a subset of
    * the occurrence list `x` -- any character appearing in `y` must
    * appear in `x`, and its frequency in `y` must be smaller or equal
    * than its frequency in `x`.
    *
    * Note: the resulting value is an occurrence - meaning it is sorted
    * and has no zero-entries.
    */
  def subtract(x: Occurrences, y: Occurrences): Occurrences =
    y.foldLeft(SortedMap[Char, Int]() ++ x) { case (xx, (c, n)) => xx.updated(c, xx(c) - n) }.toList.filter(_._2 > 0)

  /** Returns a list of all anagram sentences of the given sentence.
    *
    * An anagram of a sentence is formed by taking the occurrences of all the characters of
    * all the words in the sentence, and producing all possible combinations of words with those characters,
    * such that the words have to be from the dictionary.
    *
    * The number of words in the sentence and its anagrams does not have to correspond.
    * For example, the sentence `List("I", "love", "you")` is an anagram of the sentence `List("You", "olive")`.
    *
    * Also, two sentences with the same words but in a different order are considered two different anagrams.
    * For example, sentences `List("You", "olive")` and `List("olive", "you")` are different anagrams of
    * `List("I", "love", "you")`.
    *
    * Here is a full example of a sentence `List("Yes", "man")` and its anagrams for our dictionary:
    *
    * List(
    * List(en, as, my),
    * List(en, my, as),
    * List(man, yes),
    * List(men, say),
    * List(as, en, my),
    * List(as, my, en),
    * List(sane, my),
    * List(Sean, my),
    * List(my, en, as),
    * List(my, as, en),
    * List(my, sane),
    * List(my, Sean),
    * List(say, men),
    * List(yes, man)
    * )
    *
    * The different sentences do not have to be output in the order shown above - any order is fine as long as
    * all the anagrams are there. Every returned word has to exist in the dictionary.
    *
    * Note: in case that the words of the sentence are in the dictionary, then the sentence is the anagram of itself,
    * so it has to be returned in this list.
    *
    * Note: There is only one anagram of an empty sentence.
    */
  def sentenceAnagrams(sentence: Sentence): List[Sentence] = {
    def rec(occurrences: Occurrences): List[Sentence] = occurrences match {
      case Nil => List(List())
      case _ => {
        for {
          subset <- combinations(occurrences)
          word <- dictionaryByOccurrences.getOrElse(subset, List())
          subsentence <- rec(subtract(occurrences, subset))
        } yield word :: subsentence
      }
    }

    rec(sentenceOccurrences(sentence))
  }
}
	package forcomp

	import scala.collection.immutable._

	object Anagrams {

	/** A word is simply a `String`. */
	type Word = String

	/** A sentence is a `List` of words. */
	type Sentence = List[Word]

	/** `Occurrences` is a `List` of pairs of characters and positive integers saying
	* how often the character appears.
	* This list is sorted alphabetically w.r.t. to the character in each pair.
	* All characters in the occurrence list are lowercase.
	*
	* Any list of pairs of lowercase characters and their frequency which is not sorted
	* is not an occurrence list.
	*
	* Note: If the frequency of some character is zero, then that character should not be
	* in the list.
	*/
	type Occurrences = List[(Char, Int)]

	/** The dictionary is simply a sequence of words.
	* It is predefined and obtained as a sequence using the utility method `loadDictionary`.
	*/
	val dictionary: List[Word] = loadDictionary

	/** Converts the word into its character occurrence list.
	*
	* Note: the uppercase and lowercase version of the character are treated as the
	* same character, and are represented as a lowercase character in the occurrence list.
	*
	* Note: you must use `groupBy` to implement this method!
	*/
	def wordOccurrences(w: Word): Occurrences = w.toLowerCase.groupBy(c => c).map { case (c, l) => (c, l.length) }.toList.sortBy(_._1)

	/** Converts a sentence into its character occurrence list. */
	def sentenceOccurrences(s: Sentence): Occurrences = wordOccurrences(s.mkString)

	/** The `dictionaryByOccurrences` is a `Map` from different occurrences to a sequence of all
	* the words that have that occurrence count.
	* This map serves as an easy way to obtain all the anagrams of a word given its occurrence list.
	*
	* For example, the word "eat" has the following character occurrence list:
	*
	* `List(('a', 1), ('e', 1), ('t', 1))`
	*
	* Incidentally, so do the words "ate" and "tea".
	*
	* This means that the `dictionaryByOccurrences` map will contain an entry:
	*
	* List(('a', 1), ('e', 1), ('t', 1)) -> Seq("ate", "eat", "tea")
	*
	*/
	lazy val dictionaryByOccurrences: Map[Occurrences, List[Word]] = dictionary.groupBy(w => wordOccurrences(w))

	/** Returns all the anagrams of a given word. */
	def wordAnagrams(word: Word): List[Word] = dictionaryByOccurrences.getOrElse(wordOccurrences(word), List())

	/** Returns the list of all subsets of the occurrence list.
	* This includes the occurrence itself, i.e. `List(('k', 1), ('o', 1))`
	* is a subset of `List(('k', 1), ('o', 1))`.
	* It also include the empty subset `List()`.
	*
	* Example: the subsets of the occurrence list `List(('a', 2), ('b', 2))` are:
	*
	* List(
	* List(),
	* List(('a', 1)),
	* List(('a', 2)),
	* List(('b', 1)),
	* List(('a', 1), ('b', 1)),
	* List(('a', 2), ('b', 1)),
	* List(('b', 2)),
	* List(('a', 1), ('b', 2)),
	* List(('a', 2), ('b', 2))
	* )
	*
	* Note that the order of the occurrence list subsets does not matter -- the subsets
	* in the example above could have been displayed in some other order.
	*/
	def combinations(occurrences: Occurrences): List[Occurrences] = occurrences match {
	case Nil => List(List())
	case (c, n) :: xs =>
	val subComb = combinations(xs)
	val curComb = (1 to n).map(i => (c, i))
	val mixComb = (for {
	charOcc <- curComb
	o <- subComb
	} yield charOcc :: o).toList
	// Looks bad but works...
	mixComb ++ subComb ++ curComb.map(o => List(o))
	}

	/** Subtracts occurrence list `y` from occurrence list `x`.
	*
	* The precondition is that the occurrence list `y` is a subset of
	* the occurrence list `x` -- any character appearing in `y` must
	* appear in `x`, and its frequency in `y` must be smaller or equal
	* than its frequency in `x`.
	*
	* Note: the resulting value is an occurrence - meaning it is sorted
	* and has no zero-entries.
	*/
	def subtract(x: Occurrences, y: Occurrences): Occurrences =
	y.foldLeft(SortedMap[Char, Int]() ++ x) { case (xx, (c, n)) => xx.updated(c, xx(c) - n) }.toList.filter(_._2 > 0)

	/** Returns a list of all anagram sentences of the given sentence.
	*
	* An anagram of a sentence is formed by taking the occurrences of all the characters of
	* all the words in the sentence, and producing all possible combinations of words with those characters,
	* such that the words have to be from the dictionary.
	*
	* The number of words in the sentence and its anagrams does not have to correspond.
	* For example, the sentence `List("I", "love", "you")` is an anagram of the sentence `List("You", "olive")`.
	*
	* Also, two sentences with the same words but in a different order are considered two different anagrams.
	* For example, sentences `List("You", "olive")` and `List("olive", "you")` are different anagrams of
	* `List("I", "love", "you")`.
	*
	* Here is a full example of a sentence `List("Yes", "man")` and its anagrams for our dictionary:
	*
	* List(
	* List(en, as, my),
	* List(en, my, as),
	* List(man, yes),
	* List(men, say),
	* List(as, en, my),
	* List(as, my, en),
	* List(sane, my),
	* List(Sean, my),
	* List(my, en, as),
	* List(my, as, en),
	* List(my, sane),
	* List(my, Sean),
	* List(say, men),
	* List(yes, man)
	* )
	*
	* The different sentences do not have to be output in the order shown above - any order is fine as long as
	* all the anagrams are there. Every returned word has to exist in the dictionary.
	*
	* Note: in case that the words of the sentence are in the dictionary, then the sentence is the anagram of itself,
	* so it has to be returned in this list.
	*
	* Note: There is only one anagram of an empty sentence.
	*/
	def sentenceAnagrams(sentence: Sentence): List[Sentence] = {
	def rec(occurrences: Occurrences): List[Sentence] = occurrences match {
	case Nil => List(List())
	case _ => {
	for {
	subset <- combinations(occurrences)
	word <- dictionaryByOccurrences.getOrElse(subset, List())
	subsentence <- rec(subtract(occurrences, subset))
	} yield word :: subsentence
	}
	}

	rec(sentenceOccurrences(sentence))
	}
	}