loalf/TweetSet.scala

## TweetSet.scala
package objsets

import common._
import TweetReader._

/**
 * A class to represent tweets.
 */
class Tweet(val user: String, val text: String, val retweets: Int) {
  override def toString: String = text + "[" + retweets + "]"
}

/**
 * This represents a set of objects of type `Tweet` in the form of a binary search
 * tree. Every branch in the tree has two children (two `TweetSet`s). There is an
 * invariant which always holds: for every branch `b`, all elements in the left
 * subtree are smaller than the tweet at `b`. The eleemnts in the right subtree are
 * larger.
 *
 * Note that the above structure requires us to be able to compare two tweets (we
 * need to be able to say which of two tweets is larger, or if they are equal). In
 * this implementation, the equality / order of tweets is based on the tweet's text
 * (see `def incl`). Hence, a `TweetSet` could not contain two tweets with the same
 * text from different users.
 *
 *
 * The advantage of representing sets as binary search trees is that the elements
 * of the set can be found quickly. If you want to learn more you can take a look
 * at the Wikipedia page [1], but this is not necessary in order to solve this
 * assignment.
 *
 * [1] http://en.wikipedia.org/wiki/Binary_search_tree
 */
abstract class TweetSet {

  def isEmpty: Boolean

  def elem: Tweet

  /**
   * This method takes a predicate and returns a subset of all the elements
   * in the original set for which the predicate is true.
   *
   * Question: Can we implment this method here, or should it remain abstract
   * and be implemented in the subclasses?
   */
  def filter(p: Tweet => Boolean): TweetSet = {
    filterAcc(p, new Empty())
  }

  /**
   * This is a helper method for `filter` that propagetes the accumulated tweets.
   */
  def filterAcc(p: Tweet => Boolean, acc: TweetSet): TweetSet

  /**
   * Returns a new `TweetSet` that is the union of `TweetSet`s `this` and `that`.
   *
   * Question: Should we implment this method here, or should it remain abstract
   * and be implemented in the subclasses?
   */
   def union(that: TweetSet): TweetSet = that.filterAcc( t => !this.contains(t), this)

  /**
   * Returns the tweet from this set which has the greatest retweet count.
   *
   * Calling `mostRetweeted` on an empty set should throw an exception of
   * type `java.util.NoSuchElementException`.
   *
   * Question: Should we implment this method here, or should it remain abstract
   * and be implemented in the subclasses?
   */
  def mostRetweeted: Tweet

  /**
   * Returns a list containing all tweets of this set, sorted by retweet count
   * in descending order. In other words, the head of the resulting list should
   * have the highest retweet count.
   *
   * Hint: the method `remove` on TweetSet will be very useful.
   * Question: Should we implment this method here, or should it remain abstract
   * and be implemented in the subclasses?
   */
  def descendingByRetweet: TweetList = {
    descendingByRetweetAcc(mostRetweeted, this.remove(mostRetweeted), new Cons(mostRetweeted, Nil))
  }

  def descendingByRetweetAcc(tw: Tweet, ts: TweetSet, tl: TweetList): TweetList = {
    if (ts.isEmpty) tl
    else {
      val mr = ts.mostRetweeted
      descendingByRetweetAcc(mr, ts.remove(mr), tl.append(mr))
    }
  }


  /**
   * The following methods are already implemented
   */

  /**
   * Returns a new `TweetSet` which contains all elements of this set, and the
   * the new element `tweet` in case it does not already exist in this set.
   *
   * If `this.contains(tweet)`, the current set is returned.
   */
  def incl(tweet: Tweet): TweetSet

  /**
   * Returns a new `TweetSet` which excludes `tweet`.
   */
  def remove(tweet: Tweet): TweetSet

  /**
   * Tests if `tweet` exists in this `TweetSet`.
   */
  def contains(tweet: Tweet): Boolean

  /**
   * This method takes a function and applies it to every element in the set.
   */
  def foreach(f: Tweet => Unit): Unit
}

class Empty extends TweetSet {

  def elem = new Tweet("","",0)

  def isEmpty = true

  def filterAcc(p: Tweet => Boolean, acc: TweetSet): TweetSet = acc

  def mostRetweeted: Tweet = throw new NoSuchElementException

  /**
   * The following methods are already implemented
   */

  def contains(tweet: Tweet): Boolean = false

  def incl(tweet: Tweet): TweetSet = new NonEmpty(tweet, new Empty, new Empty)

  def remove(tweet: Tweet): TweetSet = this

  def foreach(f: Tweet => Unit): Unit = ()

  override def toString = "."
}

class NonEmpty(val elem: Tweet, left: TweetSet, right: TweetSet) extends TweetSet {

  def isEmpty = false

  def filterAcc(p: Tweet => Boolean, acc: TweetSet): TweetSet = {
    right.filterAcc(p, left.filterAcc(p, if (p(this.elem)) acc.incl(elem) else acc ))
  }

  def mostRetweetedAcc(tw: Tweet, ts: TweetSet): Tweet = {
	  val funnel = ts.filter( t => t.retweets > tw.retweets)
      if (funnel.isEmpty ) tw
      else mostRetweetedAcc(funnel.elem, funnel)
  }

  def mostRetweeted: Tweet = {
	  mostRetweetedAcc(elem, this)
  }

  /**
   * The following methods are already implemented
   */

  def contains(x: Tweet): Boolean =
    if (x.text < elem.text) left.contains(x)
    else if (elem.text < x.text) right.contains(x)
    else true

  def incl(x: Tweet): TweetSet = {
    if (x.text < elem.text) new NonEmpty(elem, left.incl(x), right)
    else if (elem.text < x.text) new NonEmpty(elem, left, right.incl(x))
    else this
  }

  def remove(tw: Tweet): TweetSet =
    if (tw.text < elem.text) new NonEmpty(elem, left.remove(tw), right)
    else if (elem.text < tw.text) new NonEmpty(elem, left, right.remove(tw))
    else left.union(right)

  def foreach(f: Tweet => Unit): Unit = {
    f(elem)
    left.foreach(f)
    right.foreach(f)
  }

  override def toString: String = "{" + left + elem + right + "}"

}

trait TweetList {
  def head: Tweet
  def tail: TweetList
  def isEmpty: Boolean
  def foreach(f: Tweet => Unit): Unit =
    if (!isEmpty) {
      f(head)
      tail.foreach(f)
    }

  def append(t: Tweet): TweetList = {
    if (isEmpty) new Cons(t, Nil)
    else new Cons(head, tail.append(t))
  }
}

object Nil extends TweetList {
  def head = throw new java.util.NoSuchElementException("head of EmptyList")
  def tail = throw new java.util.NoSuchElementException("tail of EmptyList")
  def isEmpty = true
}

class Cons(val head: Tweet, val tail: TweetList) extends TweetList {
  def isEmpty = false
}


object GoogleVsApple {
  val google = List("android", "Android", "galaxy", "Galaxy", "nexus", "Nexus")
  val apple = List("ios", "iOS", "iphone", "iPhone", "ipad", "iPad")

  lazy val googleTweets: TweetSet = TweetReader.allTweets.filter( tw => google.exists(s => tw.text.contains(s)) )
  lazy val appleTweets: TweetSet = TweetReader.allTweets.filter( tw => apple.exists(s => tw.text.contains(s)) )

  /**
   * A list of all tweets mentioning a keyword from either apple or google,
   * sorted by the number of retweets.
   */
  lazy val trending: TweetList = googleTweets.union(appleTweets).descendingByRetweet
}

object Main extends App {
  // Print the trending tweets
  GoogleVsApple.trending foreach println
}
	package objsets

	import common._
	import TweetReader._

	/**
	* A class to represent tweets.
	*/
	class Tweet(val user: String, val text: String, val retweets: Int) {
	override def toString: String = text + "[" + retweets + "]"
	}

	/**
	* This represents a set of objects of type `Tweet` in the form of a binary search
	* tree. Every branch in the tree has two children (two `TweetSet`s). There is an
	* invariant which always holds: for every branch `b`, all elements in the left
	* subtree are smaller than the tweet at `b`. The eleemnts in the right subtree are
	* larger.
	*
	* Note that the above structure requires us to be able to compare two tweets (we
	* need to be able to say which of two tweets is larger, or if they are equal). In
	* this implementation, the equality / order of tweets is based on the tweet's text
	* (see `def incl`). Hence, a `TweetSet` could not contain two tweets with the same
	* text from different users.
	*
	*
	* The advantage of representing sets as binary search trees is that the elements
	* of the set can be found quickly. If you want to learn more you can take a look
	* at the Wikipedia page [1], but this is not necessary in order to solve this
	* assignment.
	*
	* [1] http://en.wikipedia.org/wiki/Binary_search_tree
	*/
	abstract class TweetSet {

	def isEmpty: Boolean

	def elem: Tweet

	/**
	* This method takes a predicate and returns a subset of all the elements
	* in the original set for which the predicate is true.
	*
	* Question: Can we implment this method here, or should it remain abstract
	* and be implemented in the subclasses?
	*/
	def filter(p: Tweet => Boolean): TweetSet = {
	filterAcc(p, new Empty())
	}

	/**
	* This is a helper method for `filter` that propagetes the accumulated tweets.
	*/
	def filterAcc(p: Tweet => Boolean, acc: TweetSet): TweetSet

	/**
	* Returns a new `TweetSet` that is the union of `TweetSet`s `this` and `that`.
	*
	* Question: Should we implment this method here, or should it remain abstract
	* and be implemented in the subclasses?
	*/
	def union(that: TweetSet): TweetSet = that.filterAcc( t => !this.contains(t), this)

	/**
	* Returns the tweet from this set which has the greatest retweet count.
	*
	* Calling `mostRetweeted` on an empty set should throw an exception of
	* type `java.util.NoSuchElementException`.
	*
	* Question: Should we implment this method here, or should it remain abstract
	* and be implemented in the subclasses?
	*/
	def mostRetweeted: Tweet

	/**
	* Returns a list containing all tweets of this set, sorted by retweet count
	* in descending order. In other words, the head of the resulting list should
	* have the highest retweet count.
	*
	* Hint: the method `remove` on TweetSet will be very useful.
	* Question: Should we implment this method here, or should it remain abstract
	* and be implemented in the subclasses?
	*/
	def descendingByRetweet: TweetList = {
	descendingByRetweetAcc(mostRetweeted, this.remove(mostRetweeted), new Cons(mostRetweeted, Nil))
	}

	def descendingByRetweetAcc(tw: Tweet, ts: TweetSet, tl: TweetList): TweetList = {
	if (ts.isEmpty) tl
	else {
	val mr = ts.mostRetweeted
	descendingByRetweetAcc(mr, ts.remove(mr), tl.append(mr))
	}
	}


	/**
	* The following methods are already implemented
	*/

	/**
	* Returns a new `TweetSet` which contains all elements of this set, and the
	* the new element `tweet` in case it does not already exist in this set.
	*
	* If `this.contains(tweet)`, the current set is returned.
	*/
	def incl(tweet: Tweet): TweetSet

	/**
	* Returns a new `TweetSet` which excludes `tweet`.
	*/
	def remove(tweet: Tweet): TweetSet

	/**
	* Tests if `tweet` exists in this `TweetSet`.
	*/
	def contains(tweet: Tweet): Boolean

	/**
	* This method takes a function and applies it to every element in the set.
	*/
	def foreach(f: Tweet => Unit): Unit
	}

	class Empty extends TweetSet {

	def elem = new Tweet("","",0)

	def isEmpty = true

	def filterAcc(p: Tweet => Boolean, acc: TweetSet): TweetSet = acc

	def mostRetweeted: Tweet = throw new NoSuchElementException

	/**
	* The following methods are already implemented
	*/

	def contains(tweet: Tweet): Boolean = false

	def incl(tweet: Tweet): TweetSet = new NonEmpty(tweet, new Empty, new Empty)

	def remove(tweet: Tweet): TweetSet = this

	def foreach(f: Tweet => Unit): Unit = ()

	override def toString = "."
	}

	class NonEmpty(val elem: Tweet, left: TweetSet, right: TweetSet) extends TweetSet {

	def isEmpty = false

	def filterAcc(p: Tweet => Boolean, acc: TweetSet): TweetSet = {
	right.filterAcc(p, left.filterAcc(p, if (p(this.elem)) acc.incl(elem) else acc ))
	}

	def mostRetweetedAcc(tw: Tweet, ts: TweetSet): Tweet = {
	val funnel = ts.filter( t => t.retweets > tw.retweets)
	if (funnel.isEmpty ) tw
	else mostRetweetedAcc(funnel.elem, funnel)
	}

	def mostRetweeted: Tweet = {
	mostRetweetedAcc(elem, this)
	}

	/**
	* The following methods are already implemented
	*/

	def contains(x: Tweet): Boolean =
	if (x.text < elem.text) left.contains(x)
	else if (elem.text < x.text) right.contains(x)
	else true

	def incl(x: Tweet): TweetSet = {
	if (x.text < elem.text) new NonEmpty(elem, left.incl(x), right)
	else if (elem.text < x.text) new NonEmpty(elem, left, right.incl(x))
	else this
	}

	def remove(tw: Tweet): TweetSet =
	if (tw.text < elem.text) new NonEmpty(elem, left.remove(tw), right)
	else if (elem.text < tw.text) new NonEmpty(elem, left, right.remove(tw))
	else left.union(right)

	def foreach(f: Tweet => Unit): Unit = {
	f(elem)
	left.foreach(f)
	right.foreach(f)
	}

	override def toString: String = "{" + left + elem + right + "}"

	}

	trait TweetList {
	def head: Tweet
	def tail: TweetList
	def isEmpty: Boolean
	def foreach(f: Tweet => Unit): Unit =
	if (!isEmpty) {
	f(head)
	tail.foreach(f)
	}

	def append(t: Tweet): TweetList = {
	if (isEmpty) new Cons(t, Nil)
	else new Cons(head, tail.append(t))
	}
	}

	object Nil extends TweetList {
	def head = throw new java.util.NoSuchElementException("head of EmptyList")
	def tail = throw new java.util.NoSuchElementException("tail of EmptyList")
	def isEmpty = true
	}

	class Cons(val head: Tweet, val tail: TweetList) extends TweetList {
	def isEmpty = false
	}


	object GoogleVsApple {
	val google = List("android", "Android", "galaxy", "Galaxy", "nexus", "Nexus")
	val apple = List("ios", "iOS", "iphone", "iPhone", "ipad", "iPad")

	lazy val googleTweets: TweetSet = TweetReader.allTweets.filter( tw => google.exists(s => tw.text.contains(s)) )
	lazy val appleTweets: TweetSet = TweetReader.allTweets.filter( tw => apple.exists(s => tw.text.contains(s)) )

	/**
	* A list of all tweets mentioning a keyword from either apple or google,
	* sorted by the number of retweets.
	*/
	lazy val trending: TweetList = googleTweets.union(appleTweets).descendingByRetweet
	}

	object Main extends App {
	// Print the trending tweets
	GoogleVsApple.trending foreach println
	}