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I'm currently working on an implementation of A Binary Search Tree but I'm getting errors when I try to delete a node with double child. It's not seg faulting though. the error causes an abort at

delete curr

So what I mean is that it makes it all the way down the cases and through the reassigning of nodes and then when I try to delete it aborts. Ideas? here's my BST implementation

Edit: Error occurs after

cout << "here2" << endl;

in Delete

#ifndef CTREE_H
#define CTREE_H

#include <iostream>

template<class T> class CTree
{
public:
CTree() {m_root = 0;}
~CTree() {delete m_root;}

//
// class Node
// The nested node class for objects in our tree.
//

class Node 
{
public:
    friend class CTree;

    Node() {m_ll = 0;  m_rl = 0;m_active = true;}
    Node(const T &t) {m_payload = t;  m_ll = 0;  m_rl = 0;}
    ~Node() {delete m_ll;  delete m_rl;}

    T &Data() {return m_payload;}
    const T &Data() const {return m_payload;}

private:
    Node    *m_ll;
    Node    *m_rl;
    T       m_payload;

bool m_active;
};
/********************
/********************
 *
 * Insert an element
 *
 * ******************/
void Insert(const T &t) {

    Node * tree = new Node;

    Node * parent = new Node;

    tree->m_payload = t;
    if(m_root == NULL){
//      cout << "creating root" << endl;
            m_root = tree;

        tree->m_ll=tree->m_rl = NULL;
    }
    else{

//      cout << "else insert" << endl;
        Node * curr;

        curr = m_root;

        while(curr){

            parent = curr;

            if(tree->Data() > curr->Data())

                curr = curr->m_rl;

            else
                curr = curr->m_ll;
        }

        if (tree->Data() < parent->Data())

            parent->m_ll = tree;

        else

            parent->m_rl = tree;
}

}
/**************************************
*
* put data from tree in preorder form
*
***********************************/
void Preorder(std::ostream &p_str) {
    Node * curr = new Node;

curr = m_root;

preorder(curr, p_str);

}
/***********************
*
* Find Depth of Tree
*
* ********************/
int Depth() {
    Node * curr = new Node;

curr = m_root;


int depth  = maxdepth(curr);
}

/*****************************
 *
 * find node with given payload
 *
 * ***************************/

const Node *Find(const T &t) const {}
Node *Find(const T &t) {

    Node * curr = new Node;

Node * parent = new Node;

curr = m_root;

bool flag = false;

while(curr != NULL) //if empty it will just skip this step
{
    if(curr->Data() == t){

        flag = true; //found

        break;
    }
    else{
        parent = curr;

        if( curr->Data() < t) {

            curr = curr->m_rl;
        }

        else{

            curr = curr->m_ll;
        }
    }
}

if(flag == true){

    return curr;

}
else{

    Node * temp = new Node;

    temp = NULL;

    return temp; //not found return blank node
}
}

/****************************
   *
* Delete an element without loss of parents
*
* ************************/

void Delete(const T &t)
{

    Node * curr = new Node;

Node * parent = new Node;

curr = m_root;

bool flag = false;

while(curr != NULL) //if empty it will just skip this step
{
    if(curr->Data() == t){

        flag = true; //found

        break;
    }
    else{
        parent = curr; //set new parent

        if( curr->Data() < t) {

            curr = curr->m_rl; //traverse right
        }

        else{

            curr = curr->m_ll; //traverse left
        }
    }
}
if(curr != NULL){

    //delete single leaf node
    if(curr->m_ll == NULL && curr->m_rl == NULL){

        if(parent->m_ll == curr){

            delete curr;

            parent->m_ll = NULL;

            return;
        }
        else{
            delete curr;

            parent->m_rl = NULL;

            return;
        }
    }
    //single child
    if((curr->m_ll == NULL && curr->m_rl != NULL) || ((curr->m_ll == NULL && curr->m_rl != NULL))){


        //curr is left node of parent
        if(parent->m_ll == curr){

            parent->m_ll = curr->m_rl;

            delete curr;

            return;

        }
        //curr is right node of parent
        else{

            parent->m_rl = curr->m_rl;

            delete curr;

            return;

        }
    }
    //two children 
    if((curr->m_ll != NULL && curr->m_rl != NULL)){
        cout << "two children" << endl;
    //two cases curr is m_ll of parent and curr is m_rl of parent
        if(parent->m_ll == curr){
            cout << "left child" << endl;
            //check if curr->m_rl has child node if not, easy
            if(curr->m_rl->m_rl == NULL){
                //good
                cout << "Good" << endl;
                parent->m_ll = curr->m_rl;
                cout << "here" << endl;
                curr->m_rl->m_ll = curr->m_ll;
                cout << "here2" << endl;
                delete curr;

                return;
            }
            else{
                Node * temp = new Node;

                temp = curr->m_rl;

                //find least child of curr's left child
                while(temp->m_ll != NULL){

                    temp = temp->m_ll;
                }

                //connect temp to curr's left child

                temp->m_ll = curr->m_ll;

                parent->m_ll = temp;

                return;
            }
        }
    }
        else{
        //check if curr->m_ll has child node if not, easy
            if(curr->m_ll->m_rl == NULL){
                //good
                parent->m_rl = curr->m_ll;

                curr->m_ll->m_rl = curr->m_rl;  

                delete curr;
            }
            else{
                Node * temp = new Node;

                temp = curr->m_ll;

                while(temp->m_rl != NULL){

                    temp = temp->m_rl;

                }

                temp->m_rl = curr->m_rl;

                parent->m_rl = temp;
            }
    }
}
else{ 
//  cout << "No Node found " << endl;
    return;
}

}

I'm going to include my driver and my output

Driver:

using namespace std;

#include <iostream>

#include "Tree.h" 

int main(){

CTree<int> x;

x.Insert(4);
x.Insert(5);
x.Insert(3);
x.Insert(40);
x.Insert(35);
x.Insert(37);
x.Insert(34);

x.Preorder(cout);

x.Delete(35);

x.Preorder(cout);

}

Output from driver:

4 3 5 40 35 34 37 two children
left child
Good
here
here2
*** glibc detected *** a.out: double free or corruption (fasttop): 0x00000000016d6190     ***
======= Backtrace: =========
lib/libc.so.6(+0x71e16)[0x7f33efa75e16]
/lib/libc.so.6(cfree+0x6c)[0x7f33efa7ab8c]
a.out[0x401179]
a.out[0x40118e]
 a.out[0x401012]
a.out[0x400aac]
 /lib/libc.so.6(__libc_start_main+0xfd)[0x7f33efa22c8d]
  a.out[0x4008f9]
  ======= Memory map: ========


 Abort
share|improve this question
    
What is m_root and how is it initialized? –  0x499602D2 Feb 16 '13 at 1:12
    
@David see edit –  tausch86 Feb 16 '13 at 1:15
1  
Well, there's more than one call of delete curr; in the code, so help us out here - recursive code is hard enough to debug. Where does the error occur? –  Brett Hale Feb 16 '13 at 1:16
1  
If the node to be deleted is the root, then your logic will mess up (walk through it). Also, you allocate a pair of new nodes right at the start of delete - neither is needed. Instead, set parent to NULL and then add some logic further down to update m_root if parent is null. –  DrC Feb 16 '13 at 1:19
1  
Probably you should define the destructor of a tree node to get rid of the whole tree, i.e., delete (recursively) both subtrees before destroying the root. –  vonbrand Feb 16 '13 at 1:45

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