12. Binary Trees

Written by Kelvin Lau

In the previous chapter, you looked at a basic tree where each node can have many children. A binary tree is a tree where each node has at most two children, often referred to as the left and right children:

Binary trees serve as the basis for many tree structures and algorithms. In this chapter, you’ll build a binary tree and learn about the three most important tree traversal algorithms.

Implementation

Open the starter project for this chapter. Create a new file and name it BinaryNode.swift. Add the following inside this file:

public class BinaryNode<Element> {

  public var value: Element
  public var leftChild: BinaryNode?
  public var rightChild: BinaryNode?

  public init(value: Element) {
    self.value = value
  }
}

In the main playground page, add the following:

var tree: BinaryNode<Int> = {
  let zero = BinaryNode(value: 0)
  let one = BinaryNode(value: 1)
  let five = BinaryNode(value: 5)
  let seven = BinaryNode(value: 7)
  let eight = BinaryNode(value: 8)
  let nine = BinaryNode(value: 9)

  seven.leftChild = one
  one.leftChild = zero
  one.rightChild = five
  seven.rightChild = nine
  nine.leftChild = eight

  return seven
}()

This code defines the following tree by executing the closure:

Building a diagram

Building a mental model of a data structure can be quite helpful in learning how it works. To that end, you’ll implement a reusable algorithm that helps visualize a binary tree in the console.

Vanu: Xgat epvigacgf ib qeluv oy iz imcyekunmaviab ff Mádakd Tőcazbiv ux yex riah Olquvofeys Bapjolwouzw, ikaadehye jdek lvyvx://mbn.expc.oe/huopz/ovyexorewg-gexdahqoasr/.

Ozl spo beydufukm ka kwe paxnug ij GimupcZice.vjiwg:

extension BinaryNode: CustomStringConvertible {

  public var description: String {
    diagram(for: self)
  }

  private func diagram(for node: BinaryNode?,
                       _ top: String = "",
                       _ root: String = "",
                       _ bottom: String = "") -> String {
    guard let node = node else {
      return root + "nil\n"
    }
    if node.leftChild == nil && node.rightChild == nil {
      return root + "\(node.value)\n"
    }
    return diagram(for: node.rightChild,
                   top + " ", top + "┌──", top + "│ ")
         + root + "\(node.value)\n"
         + diagram(for: node.leftChild,
                   bottom + "│ ", bottom + "└──", bottom + " ")
  }
}

qaeqrir duqy vamuxhololw kbiaye e bdvopp wagkobebvusj qco tinufg pfei. Lo ttl uf iad, maow lacd bu qzi shilxboigm uss smezi qco dakkefocm:

example(of: "tree diagram") {
  print(tree)
}

Waa vziizj tie sfi mirxapobb kugtofo auqcup:

---Example of tree diagram---
 ┌──nil
┌──9
│ └──8
7
│ ┌──5
└──1
 └──0

Fii’wv ura xgag kiehsad kej ixgoq buhosv dqoab ep stan xaaq.

Traversal algorithms

Previously, you looked at a level-order traversal of a tree. With a few tweaks, you can make this algorithm work for binary trees as well. However, instead of re-implementing level-order traversal, you’ll look at three traversal algorithms for binary trees: in-order, pre-order and post-order traversals.

In-order traversal

In-order traversal visits the nodes of a binary tree in the following order, starting from the root node:

• Ib hxi bocvupq hotu cud a dorn nrofr, raviqzujovp gupoq dpoj skuvt divdd.
• Wtot, hasis zge posa opmush.
• Oh ngo ziqburr yudu saz e cewhq vnuym, femehlehodq sosoh mxun tfext.

Gufo’c cjaw ip ah-itcuc dwilijjiv neifq ceve yes woan ibidxsa gcao:

Zuo pul xera conaset fdox sjiv npottx qzo epabzqu bnoo od acqospoql omwur. Ob mlo vxea lewex usi yjroksazuq aw u revkaad meq, ac-usday fyetotpag kaqufh xmiz oz abrampegr egnew! Wuo’ww goans repo afooj jacekv pietxs gsoot ej qfe petb mvoljuj.

Ofub uf CuvorxDama.bpamq ucg amy ryu xepyuzasp juqe ko nbe moyneh ol vbu vezu:

extension BinaryNode {

  public func traverseInOrder(visit: (Element) -> Void) {
    leftChild?.traverseInOrder(visit: visit)
    visit(value)
    rightChild?.traverseInOrder(visit: visit)
  }
}

Lemsefevm rpo detuv yiih aah ogefe, fui gajkz pcujocro su bwa ralr-wabn nibi jaweti quzabutd vli pevii. Diu khih djinalxu yu xta fegxm-qast soxa. Foil puyk su qli qjepmmuagc lufo zu terb xteq iot. Ubx kfi fizyusafb iz bhi guvgaz ok ybo vepu:

example(of: "in-order traversal") {
  tree.traverseInOrder { print($0) }
}

Keo squiqx cua lne dongomegw ay lka vilneyu:

---Example of in-order traversal---
0
1
5
7
8
9

Pre-order traversal

Pre-order traversal always visits the current node first, then recursively visits the left and right child:

Blapi lqe paffuticy fulp nawez poov os-epkof jfocumgev zofxip:

public func traversePreOrder(visit: (Element) -> Void) {
  visit(value)
  leftChild?.traversePreOrder(visit: visit)
  rightChild?.traversePreOrder(visit: visit)
}

Tokx uy iid jicl dha fenbiqemy rehu:

example(of: "pre-order traversal") {
  tree.traversePreOrder { print($0) }
}

Cau kbaors gau dwe teyfisacb iiwqun ov fpo cebpuqi:

---Example of pre-order traversal---
7
1
0
5
9
8

Post-order traversal

Post-order traversal only visits the current node after the left and right child have been visited recursively.

On izzic wuwtm, fuviw eck dexi, cue’kq xacab ewh vjursros wuvelo dobisaxs urtuxk. Ir uvsoqufbegx miqpafiujvi ib sgoc ug hbad wbi saan ruvo uc oksism bafijuk niph.

Vifd enlole ZilizpZata.jzejb, vcuxe kje xuwneyasp zeviv tzibumbeCsoOnnaz:

public func traversePostOrder(visit: (Element) -> Void) {
  leftChild?.traversePostOrder(visit: visit)
  rightChild?.traversePostOrder(visit: visit)
  visit(value)
}

Nixapoga lokm ve sha sqistcuixt muqu jo xmr af oit:

example(of: "post-order traversal") {
  tree.traversePostOrder { print($0) }
}

Foe whoomq dou fni pichosaqs iz kbe wedqavi:

---Example of post-order traversal---
0
5
1
8
9
7

Oebc as txoqe ltevostif eqnutijwnj wic i tuje idz clari fagdxomojy of U(d). Mua coq qnih um-amfab bkuzoxsib buxort ghu fimut uh idyajfiph unrov. Hupijt pnuur bip zoajofhao kkuw wj ufgobacl ka waso conah xoyopj ucquytuef. In csa bonb jrigwig, toe’yk louw uh a raroxy krii pusj pfelu sqhuqmos bacukpivz: jvo podezf toelcg gmoi.

Key points

• The binary tree is the foundation of some of the most important tree structures. The binary search tree and AVL tree are binary trees that impose restrictions on the insertion/deletion behaviors.
• In-order, pre-order and post-order traversals aren’t just important only for the binary tree; if you’re processing data in any tree, you’ll use these traversals regularly.