struct binary_tree
{
int data;
binary_tree *left = nullptr, *right = nullptr;
};
type Tree_Node;
type Tree_Node_Access is access Tree_Node;
type Tree_Node is record
Value: Integer;
Left, Right: Tree_Node_Access;
end record;
struct treenode{
int value;
struct treenode* left;
struct treenode* right;
}
type treenode =
Node of {
value: int;
left: treenode;
right: treenode
}
| Leaf
class BinaryTree<T>:IComparable<T>
{
T value;
BinaryTree<T> leftChild;
BinaryTree<T> rightChild;
}
struct BinaryTree(T)
{
T data;
BinaryTree* left;
BinaryTree* right;
}
class Node<T> {
final T value;
Node<T> left, right;
Node(this.value, {this.left, this.right});
}
defmodule BinaryTree do
defstruct data: nil, left: nil, right: nil
end
-type binary_tree(T) ::
#{ data := T
, left := binary_tree(T)
, right := binary_tree(T)
}.
type binary_tree
integer :: value
type(binary_tree), allocatable :: left
type(binary_tree), allocatable :: right
end type binary_tree
type BinTree[L any] struct {
Label L
Left, Right *BinTree[L]
}
type BinTree struct {
Label valueType
Left, Right *BinTree
}
class BinTree<T extends Comparable<T>>{
T value
BinTree<T> left
BinTree<T> right
}
data BT x = BEnd | BNode (BT x) x (BT x)
class Node {
constructor (data) {
this.data = data
this.left = null
this.right = null
}
}
class BinTree<T extends Comparable<T>>{
T value;
BinTree<T> left;
BinTree<T> right;
}
interface Tree<T>{
boolean search(T x);
}
class Nil<T extends Comparable<? super T>> implements Tree<T>{
public boolean search(T x) { return false; }
}
class Node<T extends Comparable<? super T>> implements Tree<T> {
T item; Tree<T> left; Tree<T> right;
public Node(T i, Tree<T> l, Tree<T> r) {
item=i; left=l; right=r; }
public boolean search(T x) {
int cmp = x.compareTo(item);
return cmp==0 || (cmp<0 && left.search(x)) || (cmp>0 && right.search(x));
}
data class Node(
val key: Int,
val left: Node? = null,
val right: Node? = null
)
(defclass node ()
((value
:initarg :value :initform nil
:accessor node-value)
(left-child
:initarg :left-child :initform nil
:accessor node-left-child)
(right-child
:initarg :right-child :initform nil
:accessor node-right-child)))
local function BinTree(v, l, r)
return {
val = v,
left = l,
right = r
}
end
@interface Node:NSObject
@property id value; // id means any object value
@property Node *left,*right;
@end
// usage like
Node *n=[Node new];
n.value=@1;
n.left=otherNode;
n.right=anotherNode;
// somewhere needed also
@implementation Node @end
class BNode
{
public $data;
public $lNode;
public $rNode;
public function __construct($item)
{
$this->data = $item;
$this->lNode = null;
$this->rNode = null;
}
}
type
generic BinTree<T> = class
Value: T;
Left, Right: BinTree;
end;
class Tree::Binary {
has 'left', is => 'ro', isa => Maybe[InstanceOf['Tree::Binary']];
has 'right', is => 'ro', isa => Maybe[InstanceOf['Tree::Binary']];
has 'val', is => 'ro', isa => Int;
}
my $t = Tree::Binary->new(
val => 42,
left => Tree::Binary->new(val => 23),
right => Tree::Binary->new(
val => 1729,
right => Tree::Binary->new(val => -1)
)
);
__END__
42
↙ ↘
23 1729
↙ ↘ ↙ ↘
∅ ∅ ∅ -1
class Node:
def __init__(self, data):
self.data = data
self.left = None
self.right = None
class Node:
def __init__(self, data, left_child, right_child):
self.data = data
self._left_child = left_child
self._right_child = right_child
Node = Struct.new(:left, :right, :value)
parent = Node.new(Node.new, Node.new)
struct BinTree<T> {
value: T,
left: Option<Box<BinTree<T>>>,
right: Option<Box<BinTree<T>>>,
}
case class BinaryTree[T <: Ordered[T]](
value: T,
left: Option[BinaryTree[T]],
right: Option[BinaryTree[T]]
)
sealed trait Tree[T <: Ordered[T]]:
def search(x: T): Boolean
final case class Nil[T <: Ordered[T]]() extends Tree[T]:
override def search(x: T): Boolean = false
final case class Node[T <: Ordered[T]](
item: T,
left: Tree[T],
right: Tree[T]
) extends Tree[T]:
override def search(other: T): Boolean =
item compare other match
case 0 => true
case n if n < 0 => left.search(other)
case n if n > 0 => right.search(other)
(define (make-btree value left right)
(cons value (cons left right)))
(define (btree-value bt) (car bt))
(define (btree-left bt) (cadr bt))
(define (btree-right bt) (cddr bt))
Object subclass: #TreeNode
instanceVariableNames: 'left right'
classVariableNames: ''
poolDictionaries: ''
category: 'Trees'.