c++ binarysearchtree insert - c++

I'm working on a project where I have to make a binary search tree that stores strings and takes account of doubles. While i've already tackled the specifics, I can't for the life of me get this damn insert function to work. It seems to only store the root node, leaving it's "children" NULL even though it does actually seem to assign the left and right pointers to new nodes. However when I attempt to output it, only the main parent (root) node exists. I guess the changes do not get saved for whatever reason.
Here's the header file:
#ifndef BST_H
#define BST_H
#include <string>
#include <vector>
#include <iostream>
using namespace std;
typedef string ItemType;
class Node
{
public:
Node(); // constructor
ItemType data; // contains item
Node* left; // points to left child
Node* right;// points to right child
int dataCount; // keeps track of repeats
vector<int> lineNumber; // keeps track of line numbers
};
class Tree
{
public:
Tree(); // constructor
// ~Tree(); // destructor. not working.
bool isEmpty(); // tests for empty tree
Node* find(Node* root, ItemType item); // finds an item
void insert(Node* root, ItemType item, int lineN, Tree tree); // inserts an item
void outputTree(Node* root); // lists all items in tree
void treeStats(Tree tree); // outputs tree stats
void clearTree(); // erases the tree (restart)
Node* getRoot(); // returns the root
void setRoot(Node*& root);
// void getHeight(Tree *root); // gets height of tree
private:
Node* root; // root of tree
int nodeCount; // number of nodes
};
#endif
cpp:
#include "BST.h"
bool setRootQ = true;
/** Node constructor- creates a node, sets children
* to NULL and ups the count. */
Node::Node()
{
left = right = NULL;
dataCount = 1;
}
/** Tree constructor- creates instance of tree
* and sets parameters to NULL */
Tree::Tree()
{
root = NULL;
nodeCount = 0;
}
/** Destructor- deallocates tree/node data;
* avoids heap leaks. SOMETHING WRONG. CAUSES SEGFAULT
Tree::~Tree()
{
if(this->root->left) // if a left child is present
{
delete this->root->left; //recursive call to destructor ("~Tree(->left)")
this->root->left = NULL;
}
if(this->root->right) // if a right child is present
{
delete this->root->right; //recursive call to destructor
this->root->right = NULL;
}
} */
/** Returns true if tree is empty.
* Otherwise returns false (DUH). */
bool Tree::isEmpty()
{
return root == NULL;
}
/** Searches tree for item; returns the node if found
* #param root- tree node.
* item- data to look for. */
Node* Tree::find(Node* root, ItemType item)
{
if(root == NULL) // if empty node
{
return NULL;
}
else if(item == root->data) // if found
{
return root;
}
else if(item < root->data) // if item is less than node
{
find(root->left, item);
}
else if(item > root->data) // if item is more than node
{
find(root->right, item);
}
return NULL;
}
/** Adds a new node to the tree. If duplicate, increases count.
* #param item- data to insert.
* root- tree node/ */
void Tree::insert(Node* root, ItemType item, int lineN, Tree tree)
{
Node* temp = find(tree.getRoot(), item);
if(temp != NULL) // if item already exists
{
temp->dataCount += 1;
temp->lineNumber.push_back(lineN);
return;
}
if(root == NULL) // if there is an empty space
{
root = new Node; // insert new node
root->data = item; // w/ data value
root->lineNumber.push_back(lineN);
nodeCount++;
if(setRootQ)
{
setRoot(root);
setRootQ = false;
}
return;
}
if(item < root->data)
{
insert(root->left, item, lineN, tree);
}
if(item > root->data)
{
insert(root->right, item, lineN, tree);
}
}
/** Outputs tree to console in inorder.
* #param root- tree root. */
void Tree::outputTree(Node* root)
{
if(isEmpty()) // if empty tree
{
cout << "Error: No items in tree" << endl; // error message
}
else
{
if(root->left != NULL)
{
outputTree(root->left);
}
cout << "- " << root->data << " (" << root->dataCount << ") line#s: ";
for(unsigned int i = 0; i < root->lineNumber.size(); i++)
{
cout << root->lineNumber[i] << ", ";
}
cout << endl;
if(root->right != NULL)
{
outputTree(root->right);
}
}
}
/** Displays tree stats including number of nodes,
* tree height, and more frequent item.
* #param tree- tree instance. */
void Tree::treeStats(Tree tree)
{
cout << "Number of entries: " << nodeCount << endl;
// unfinished
}
/** Clears tree.
void Tree::clearTree()
{
this->~Tree();
} */
/** Returns the root of the tree. */
Node* Tree::getRoot()
{
return root;
}
void Tree::setRoot(Node*& rootS)
{
root = rootS;
}
I realize my destructor isn't working but I'll tackle that myself later. I've been pulling my hair out over this trying to figure out what I'm missing, but to no avail. If anyone can give me any help and point me in the direction towards a solution I would greatly appreciate it.
i think it might have something to do with
void Tree::insert(Node* root, ItemType item, int lineN, Tree tree)
and instead should be something like
void Tree::insert(Node* &root, ItemType item, int lineN, Tree tree)
but when i try i get a "no matching function" error. :/

The solution you suggest yourself (with insert() taking Node *& root) will work. You have to make a corresponding change to the .h file, AND also change getRoot() to return Node *& in both .h and .cc files.
This will work. But your code has other problems. For example, setRoot and setRootQ don't do anything useful, as far as I can tell. The fourth argument to insert() only confuses things and does nothing to detect duplicates. It should be removed. To detect a duplicate simply do if (item == root->data) just before you do if (item < root->data) in the insert() method (i.e. it'll be even more similar to find()).
Also, if anyone besides you will ever use your code, you shouldn't require passing in getRoot() to methods like find() and insert(). Instead, create private helper methods, like find_helper(Node*, Item) and insert_helper(Node*&,Item), and have the public methods call them with the root node as the first argument. E.g.:
Node *find(Item item) { return find_helper(root, item); }
This would also make the weird return type of getRoot() unnecessary, and you could change it back to returning the plain Node*, or get rid of that accessor altogether.

Seems like there is a lot of pointer comparison occurring but the pointer member variables are not being initialized. Ensure that the pointer member variables are initialized properly so that they evaluate properly in if statements.
Change from:
class Node
{
public:
Node(); // constructor
...
};
to
class Node
{
public:
Node() : left(0), right(0) {}
...
};

Related

void insert(int ) method for BST tree/C++

I have been trying to get this function working for the longest time now. It is part of an assignment for an online course, but it seems no matter what I submit, the function fails for both the empty child test and the left child test. See code below. The main() function is deliberately commented out. Any info./input is much appreciated.
// C++ binary trees and stuff;
//
#include <iostream>
#include <cstdio>
#include <string>
#include <vector>
using namespace std;
class BST
{
public:
int data;
BST *left;
BST *right;
//BST *root;
// BST() constructor
BST (int num)
{
data = num;
left = nullptr;
right = nullptr;
root = nullptr;
}
// constructors for root node(s), initializing as root when no values exist yet;
BST() : root (nullptr){}
BST (BST *rootNode) : root(rootNode){}
void insert (int value)
{
BST *newNode = new BST();
newNode = root;
if (root == nullptr)
{
root = new BST (value);
}
else
{
root->data = value;
}
// check if newNode's value equals the passed-in value:
if (value == root->data)
{
//cout << "\nWarning! Value already exists in tree, so nothing will be done.\n";
return;
}
// check if value is < or > newNode's value:
if (value <= root->data)
{
if (root->left == nullptr)
{
// make a new node as the left child of this node,
root->left = new BST(value);
}
else
{
// recursively call insert() on tree's left side,
root->left->insert(value);
}
}
else
{
if (root->right == nullptr)
{
// make a new node as the right child of this node,
root->right = new BST(value);
}
else
{
// recursively call insert() on tree's right side,
root->right->insert(value);
}
}
}
public:
BST *root;
};
/*
int main (int argc, char *argv[])
{
//...insert code here,
// create nodes,...
BST rootNode(5);
BST leftNode(4);
BST rightNode(6);
// connect the nodes to the tree via rootNode.left and rootNode.right,..
rootNode.left = &leftNode;
rootNode.right = &rightNode;
printf ("\nData (root) value = %i, rootNode.left = %i, and rootNode.right = %i\n",
rootNode.data, rootNode.left->data, rootNode.right->data);
cout << "\n\nHello, Solar System!\n";
return 0;
}
*/
Okay, here's my suggestion. You need to reformat your code. You need two classes. You need a BST, and you need a Node. The various methods to add/remove/traverse are part of the BST class. Nodes are just Nodes.
So:
class BST_Node {
public:
int value;
BST_Node * left = nullptr;
BST_Node * right = nullptr;
// Define constructors, etc.
};
class BST {
public:
BST_Node * root = nullptr;
BST_Node * insert(int value);
void insertNode(BST_Node *node);
void insertNodeBelow(BST_Node *nodeToInsert, BST_Node *startingNode);
};
BST_Node * BST::insert(int value) {
BST_Node * node = new BST_Node(value);
insertNode(node);
return node;
}
void BST::insertNode(BST_Node *node) {
if (node == nullptr) {
return;
}
if (root == nullptr) {
root = node;
}
else {
insertNodeBelow(node, root);
}
}
void BST::insertNodeBelow(BST_Node *node, BST_Node *startingNode) {
if (node == nullptr || startingNode == nullptr) {
return;
}
if (node->value < startingNode->value) {
if (startingNode->left != nullptr) {
insertNodeBelow(node, startingNode->left);
}
else {
startingNode->left = node;
}
}
else {
if (startingNode->right != nullptr) {
insertNodeBelow(node, startingNode->right);
}
else {
startingNode->right = node;
}
}
}
How this works... First, the logic of how to store nodes is in BST. Nodes don't care. Second, I made methods for either inserting a value or a node. Because I think that's handy. That should be fairly easy to understand.
The root node can be null, if so, then your inserted node is now root. Otherwise it calls the recursive insertion function. Now, you could simplify this a little, but I didn't want to get too clever.
So it's simple. We look to see where it belongs relative to the point we're at (initially the root). Either we go into the left branch or the right branch. But that branch could be empty, so you just plop it right in. If it's not empty, then you recurse.
I didn't test it.

Creating a binary Tree and search function

I am creating a binary tree and want to just Search function but I want to know how many nodes are visited to find a value. in the search function.
Here is the hearder file
#ifndef INTBINARYTREE_H
#define INTBINARYTREE_H
class IntBinaryTree
{
private:
struct TreeNode
{
int value; // The value in node .
TreeNode *left; //pointer to left node
TreeNode *right; // Pointer to right child node
};
TreeNode *root;
//private member functions
void insert(TreeNode *&,TreeNode *&);
void displayInOrder(TreeNode *) const;
void displayPreOrder(TreeNode *) const;
void displayPostOrder(TreeNode *) const;
public:
IntBinaryTree()
{
root = nullptr;
}
// Binary search tree
int searchNode(int);
void insertNode(int);
void displayInOrder() const
{
displayInOrder(root);
}
#endif // INTBINARYTREE_H
And here is the .cpp File I want to know how to for the search function if a value is not found zero and if value is found how many nodes are visited ?
#include "IntBinaryTree.h"
void IntBinaryTree::insert(TreeNode *&nodePtr, TreeNode *&newNode)
{
if (nodePtr == nullptr)
nodePtr=newNode; // insert the node
else if (newNode->value < nodePtr->value) `//search the left branch`
insert(nodePtr->left, newNode);
else
insert(nodePtr->right, newNode); //search the right branch
}
void IntBinaryTree::insertNode(int num)
{
TreeNode *newNode= nullptr; // pointer to a new node
//create a new node and store num in it
newNode = new TreeNode;
newNode->value= num;
newNode->left = newNode->right = nullptr;
//insert the node
insert(root, newNode);
}
int IntBinaryTree::searchNode(int num)
{
TreeNode *nodePtr = root;
while(nodePtr)
{
if (nodePtr->value==num)
{
cout<<"Node found"<<num<<endl;
}
else if (num < nodePtr->value)
nodePtr = nodePtr->left; // look to the left side of the branch if less than the value of the node
else
nodePtr = nodePtr->right; // look to the right side of the if not less than the value .
}
return 0;
}
Here is the Mainfile
#include <iostream>
#include "IntBinaryTree.h"
using namespace std;
int main()
{
IntBinaryTree tree;
cout << "inserting nodes" << endl;
tree.insertNode(5);
tree.insertNode(8);
tree.insertNode(3);
tree.insertNode(12);
tree.insertNode(9);
cout << "Done.\n";
tree.searchNode(5);
return 0;}
Can you please code it for me and edit and explain it briefly how does it work ?
Your includes are wrong.
There is a #include "IntBinaryTree.cpp" in your main.cpp. Because of this the insert member (and many others) exist twice. General rule: Never include cpp files.
Just remove the line, and you should be fine.

Binary Search Tree Problem with Insert Function

Hello i am new to c++ and learning about binary search trees.
I am trying to implement a simple binary search tree where i can store "KeyCodePair" object(which has string and integer) and doing some operations on tree like search and insert. Seems like there are some problems with my logic thats why first Insert function is working but second is not working(calling them from Main) I guess there is problem with the way i implemented "root" where should i write it
This is Tree.cpp:
#include "Tree.h";
#include "KeyCodePair.h";
Tree::Tree() {
treeNode* root = NULL;
}
Tree::treeNode* Tree::getNewNode(KeyCodePair data) {
treeNode* newNode = new treeNode();
newNode->data = data;
newNode->left = newNode->right = NULL;
return newNode;
}
Tree::treeNode* Tree::Insert(KeyCodePair data) {
if (root == NULL) {
root = getNewNode(data);
}
else if (data.getCode() <= root->data.getCode()) {
root->left = Insert(data);
}
else {
root->right = Insert(data);
}
return root;
}
bool Tree::Search(KeyCodePair data) {
if (root == NULL) {
return false;
}
else if (root->data.getCode() == data.getCode()) {
return true;
}
else if (data.getCode() <= root->data.getCode()) {
return Search(data);
}
else {
return Search(data);
}
}
Tree.h:
#ifndef TREE_H
#define TREE_H
#include "KeyCodePair.h"
class Tree {
private:
struct treeNode {
KeyCodePair data;
treeNode* left;
treeNode* right;
} ;
treeNode* root;
public:
treeNode* Insert( KeyCodePair data);
bool Search(KeyCodePair data);
treeNode* getNewNode(KeyCodePair data);
Tree();
};
#endif
KeyCodePair.cpp
#include "KeyCodePair.h"
KeyCodePair::KeyCodePair(string keyparam, int codeparam) {
key = keyparam;
code = codeparam;
}
KeyCodePair::KeyCodePair() {
}
string KeyCodePair::getKey() {
return key;
}
int KeyCodePair::getCode() {
return code;
}
KeyCodePair.h
#ifndef KEYCODEPAIR_H
#define KEYCODEPAIR_H
#include <iostream>
using namespace std;
class KeyCodePair {
private:
string key;
int code;
public:
KeyCodePair();
KeyCodePair(string key, int code);
string getKey();
int getCode();
};
#endif
And Finally this is the main:
#include <iostream>
#include <string>
#include "Tree.h"
#include "KeyCodePair.h"
using namespace std;
int main()
{
Tree tree = Tree();
KeyCodePair testPair = KeyCodePair("teststring1",10);
KeyCodePair qwePair = KeyCodePair("teststring2", 20);
cout << tree.Insert(testPair) << endl;
cout << tree.Insert(qwePair) << endl; // problem on second insert
if (tree.Search(testPair) == true) cout << "Found\n";
else cout << "Not Found\n";
cin.get();
return 0;
}
Let's take a look at your insert function:
Tree::treeNode* Tree::Insert(KeyCodePair data) {
if (root == NULL) {
root = getNewNode(data);
}
else if (data.getCode() <= root->data.getCode()) {
root->left = Insert(data);
}
else {
root->right = Insert(data);
}
return root;
}
What you do here is you take in the data to be inserted, and you look at the root. If there is no root, you add a new node containing the data and assign that to the root (which is why your first insert works). However, once there is a root, you then figure out if the new node should be placed to the left or right of the root, and then recursively call Insert() with the same data. This next call to Insert will do nothing different, and look at the same root of the tree over and over to most likely produce an infinite loop.
What you have to do is using your data, first traverse all the way down the tree to the position at which you want to insert your node, then insert it and assign the pointers. Some code for this might look like so:
Tree::Insert(KeyCodePair data) {
// currPos will end up being the position where we want to insert
Tree::treeNode* currPos = root;
while (currPos != NULL) {
if (data.getCode() <= currPos->data.getCode())
currPos = currPos->left;
else if (data.getCode() > currPos->data.getCode())
currPos = currPos->right;
}
// Insert at currPos and reassign the left or right pointer of
// the parent
}
The problem is that your insert only considers the root node. You need to traverse down the tree to the point where you do the insert:
class Tree {
...
public:
treeNode* Insert(KeyCodePair data);
...
};
Step 1: Change your interface
class Tree {
...
// The insert that does the work
// We pass in the current position in the tree.
treeNode* Insert(treeNode* node, KeyCodePair data);
public:
// The public interface that accepts the data and calls the internal Insert
void Insert(KeyCodePair data);
...
};
Step 2: Use the public Insert to call the internal Insert.
void Tree::Insert(KeyCodePair data) {
// Use the internal Insert() passing the root as the starting point.
// If a new value is needed it will be returned otherwise the original
// value is returned.
root = Insert(root, data);
}
Step 3: Modify the OP Insert into an Internal Insert.
Tree::treeNode* Tree::Insert(treeNode* node, KeyCodePair data) {
if (node == NULL) {
// If we have reached the tip of the tree then
// return the new node so it can be inserted.
return getNewNode(data);
}
// Otherwise we have a node so we need to find the node
// were the data will be inserted.
// so move to the next level. Assign the result as the next
// level could be null.
if (data.getCode() <= root->data.getCode()) {
node->left = Insert(node->left, data);
}
else {
node->right = Insert(node->right, data);
}
// Return this node
// So it stays in the chain.
return node;
}

C++ Linked List assignment: trouble with insertion and deletion

I am working on a linked list implementation in C++. I am making progress but am having trouble getting the insertion functionality and deletion functionality to work correctly. Below is list object in the C++ header file:
#ifndef linkList_H
#define linkList_h
//
// Create an object to represent a Node in the linked list object
// (For now, the objects to be put in the list will be integers)
//
struct Node
{
Node() : sentinel(0) {}
int number;
Node* next;
Node* prev;
Node* sentinel;
};
//
// Create an object to keep track of all parts in the list
//
class List
{
public:
//
// Contstructor intializes all member data
//
List() : m_listSize(0), m_listHead(0) {}
//
// methods to return size of list and list head
//
Node* getListHead() const { return m_listHead; }
unsigned getListSize() const { return m_listSize; }
//
// method for adding and inserting a new node to the linked list,
// retrieving and deleting a specified node in the list
//
void addNode(int num);
void insertNode(Node* current);
void deleteNode(Node* current);
Node* retrieveNode(unsigned position);
private:
//
// member data consists of an unsigned integer representing
// the list size and a pointer to a Node object representing head
//
Node* m_listHead;
unsigned m_listSize;
};
#endif
And here is the implementation (.cpp) file:
#include "linkList.h"
#include <iostream>
using namespace std;
//
// Adds a new node to the linked list
//
void List::addNode(int num)
{
Node *newNode = new Node;
newNode->number = num;
newNode->next = m_listHead;
m_listHead = newNode;
++m_listSize;
}
//
// NOTWORKING: Inserts a node which has already been set to front
// of the list
//
void List::insertNode(Node* current)
{
// check to see if current node already at
// head of list
if(current == m_listHead)
return;
current->next = m_listHead;
if(m_listHead != 0)
m_listHead->prev = current;
m_listHead = current;
current->prev = 0;
}
//
// NOTWORKING: Deletes a node from a specified position in linked list
//
void List::deleteNode(Node* current)
{
current->prev->next = current->next;
current->next->prev = current->prev;
}
//
// Retrieves a specified node from the list
//
Node* List::retrieveNode(unsigned position)
{
if(position > (m_listSize-1) || position < 0)
{
cout << "Can't access node; out of list bounds";
cout << endl;
cout << endl;
exit(EXIT_FAILURE);
}
Node* current = m_listHead;
unsigned pos = 0;
while(current != 0 && pos != position)
{
current = current->next;
++pos;
}
return current;
}
After running a brief test program in the client C++ code, here is the resulting output:
Number of nodes: 10
Elements in each node:
9 8 7 6 5 4 3 2 1 0
Insertion of node 5 at the list head:
4 9 8 7 6 5 4 9 8 7
Deletion of node 5 from the linked list
As you can see, the insertion is not simply moving node 5 to head of list, but is overwriting other nodes beginning at the third position. The pseudo code I tried to implement came from the MIT algorithms book:
LIST-INSERT(L, x)
next[x] <- head[L]
if head[L] != NIL
then prev[head[L]] <- x
head[L] <- x
prev[x] <- NIL
Also the deletion implementation is just crashing when the method is called. Not sure why; but here is the corresponding pseudo-code:
LIST-DELET'
next[prev[x]] <- next[x]
prev[next[x]] <- prev[x]
To be honest, I am not sure how the previous, next and sentinel pointers are actually working in memory. I know what they should be doing in a practical sense, but looking at the debugger it appears these pointers are not pointing to anything in the case of deletion:
(*current).prev 0xcdcdcdcd {number=??? next=??? prev=??? ...} Node *
number CXX0030: Error: expression cannot be evaluated
next CXX0030: Error: expression cannot be evaluated
prev CXX0030: Error: expression cannot be evaluated
sentinel CXX0030: Error: expression cannot be evaluated
Any help would be greatly appreciated!!
You have got an error in addNode(). Until you fix that, you can't expect insertNode to work.
Also, I think your design is quite silly. For example a method named "insertNode" should insert a new item at arbitrary position, but your method insertNode does a pretty different thing, so you should rename it. Also addNode should be renamed. Also as glowcoder wrote, why are there so many sentinels? I am affraid your class design is bad as a whole.
The actual error is that you forgot to set prev attribute of the old head. It should point to the new head.
void List::addNode(int num)
{
Node *newNode = new Node;
newNode->number = num;
newNode->next = m_listHead;
if(m_listHead) m_listHead->prev = newNode;
m_listHead = newNode;
++m_listSize;
}
Similarly, you have got another error in deleteNode(). It doesn't work when deleting last item from list.
void List::deleteNode(Node* current)
{
m_listSize--;
if(current == m_listHead) m_listHead = current->next;
if(current->prev) current->prev->next = current->next;
if(current->next) current->next->prev = current->prev;
}
Now you can fix your so-called insertNode:
void List::insertNode(Node* current)
{
int value = current->number;
deleteNode(current);
addNode(value);
}
Please note that I wrote everything here without compiling and testing in C++ compiler. Maybe there are some bugs, but still I hope it helps you at least a little bit.
In deleteNode, you are not handling the cases where current->next and/or current->prev is null. Also, you are not updating the list head if current happens to be the head.
You should do something like this:
node* next=current->next;
node* prev=current->prev;
if (next!=null) next->prev=prev;
if (prev!=null) prev->next=next;
if (m_listhead==current) m_list_head=next;
(Warning: I have not actually tested the code above - but I think it illustrates my idea well enough)
I am not sure what exactly your InsertNode method does, so I can't offer any help there.
OK.
As #Al Kepp points out, your "add node" is buggy. Look at Al's code and fix that.
The "insert" that you are doing does not appear to be a normal list insert. Rather it seems to be a "move to the front" operation.
Notwithstanding that, you need to delete the node from its current place in the list before you add it to the beginning of the list.
Update
I think you have misunderstood how insert should work. It should insert a new node, not one that is already in the list.
See below for a bare-bones example.
#include <iostream>
// List Node Object
//
struct Node
{
Node(int n=0);
int nData;
Node* pPrev;
Node* pNext;
};
Node::Node(int n)
: nData(n)
, pPrev(NULL)
, pNext(NULL)
{
}
//
// List object
//
class CList
{
public:
//
// Contstructor
//
CList();
//
// methods to inspect list
//
Node* Head() const;
unsigned Size() const;
Node* Get(unsigned nPos) const;
void Print(std::ostream &os=std::cout) const;
//
// methods to modify list
//
void Insert(int nData);
void Insert(Node *pNew);
void Delete(unsigned nPos);
void Delete(Node *pDel);
private:
//
// Internal data
//
Node* m_pHead;
unsigned m_nSize;
};
/////////////////////////////////////////////////////////////////////////////////
CList::CList()
: m_pHead(NULL)
, m_nSize(0)
{
}
Node *CList::Head() const
{
return m_pHead;
}
unsigned CList::Size() const
{
return m_nSize;
}
void CList::Insert(int nData)
{
Insert(new Node(nData));
}
void CList::Insert(Node *pNew)
{
pNew->pNext = m_pHead;
if (m_pHead)
m_pHead->pPrev = pNew;
pNew->pPrev = NULL;
m_pHead = pNew;
++m_nSize;
}
void CList::Delete(unsigned nPos)
{
Delete(Get(nPos));
}
void CList::Delete(Node *pDel)
{
if (pDel == m_pHead)
{
// delete first
m_pHead = pDel->pNext;
if (m_pHead)
m_pHead->pPrev = NULL;
}
else
{
// delete subsequent
pDel->pPrev->pNext = pDel->pNext;
if (pDel->pNext)
pDel->pNext->pPrev = pDel->pPrev;
}
delete pDel;
--m_nSize;
}
Node* CList::Get(unsigned nPos) const
{
unsigned nCount(0);
for (Node *p=m_pHead; p; p = p->pNext)
if (nCount++ == nPos)
return p;
throw std::out_of_range("No such node");
}
void CList::Print(std::ostream &os) const
{
const char szArrow[] = " --> ";
os << szArrow;
for (Node *p=m_pHead; p; p = p->pNext)
os << p->nData << szArrow;
os << "NIL\n";
}
int main()
{
CList l;
l.Print();
for (int i=0; i<10; i++)
l.Insert((i+1)*10);
l.Print();
l.Delete(3);
l.Delete(7);
l.Print();
try
{
l.Delete(33);
}
catch(std::exception &e)
{
std::cerr << "Failed to delete 33: " << e.what() << '\n';
}
l.Print();
return 0;
}

Binary Search Tree Insertion C++ rooted at current node

I need to add an item to a binary tree given only the item to be added.
Here is the code I'm given:
void BinaryTree::add(Data * data) {
if (root == NULL) {
root = new BinaryTreeNode(data);
}
else {
root->add(data);
}
}
where root is a private variable of a BinaryTree defined as a BinaryTreeNode.
I need to implement a method:
void BinaryTreeNode::add(Data * data);
where a BinaryTreeNode is:
class BinaryTreeNode {
public:
Data * nodeData;
BinaryTreeNode * left;
BinaryTreeNode * right;
/**
* Constructor
*/
BinaryTreeNode(
Data * data,
BinaryTreeNode * left = NULL,
BinaryTreeNode *right = NULL
)
: nodeData(data), left(left), right(right)
{ }
// ...
I want to do this recursively, but I'm not positive how when you're only passed the data to be added.
My idea that doesn't work is:
void BinaryTreeNode::add(Data * newData) {
BinaryTreeNode * temp = this;
if (temp == NULL) {
temp->nodeData = newData;
} else {
if (newData->compareTo(nodeData) < 0) {
temp->left->add(newData);
} else {
temp->right->add(newData);
}
}
}
You are setting temp to this and then comparing it to NULL. this should never be NULL. You need to check if the left and right are NULL.
Well a binary tree, atleast how I know how to implement involves something like the following with two objects, one containing the the treenode object, and the other acting as an interface for the whole tree.
class cBinaryTree {
public:
bool insert(int inData);
//Other operations
private:
cBinaryTreeNode* root;
bool leftInsertion;
cBinaryTreeNode* getRoot() { return root; }
As you are comparing the actually value of the input data and placing it accordingly, this qualifies as a binary search tree. Then the insertion function can be written as
bool cBinaryTree::insert(int inData) {
//handle case if its first node.
cBinaryTreeNode *Parent = getInsertionNodePosition(getRoot(), inData);
cBinaryTreeNode *newNode = createNewNode(inData);
if(leftInsertion) //insert into left. add return statement
Parent->setLeftChild() = newNode;
else //insert into right
}
The recursive lookup function will be something like
cBinaryTreeNode* getInsertionNodePosition(cBinaryTreeNode* node,int inData) {
//Check left subtree and proceed from there.
if(inData < node->getData()) {
if(node->getLeftChild() == NULL) {
leftInsertion = true;
return node;
}
else {
node = node->getLeftChild();
return getInsertionNodePosition(node, inData);
}
}
//Similarly Check right subtree.
Hope this helps.