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I receive a segmentation fault when I try to perform a mergesort with large textfiles (7 meg or so) in my linked list. It works with smaller files (under 1 meg). How can I allocate more memory or what is wrong in the merge sort functions below? Thanks in advance!

Here is the code: (LinkedListAnyType.cpp)

/*  Miniprojekt 2
 *  LinkedListAnyType.cpp
 *
 *  By Victor Lundgren 2011-02-28.
 *  nfk10vln@student.hig.se
 */

#include <iostream>
#include <string>

using namespace std;

template <typename AnyType> // Template to allow multiple datatypes
class LinkedList {


    // Class to create a node
    class Node{

    public: AnyType data; // Data in each node
    public: Node *next; // Pointer to next node

        // Constructor
    public: Node(AnyType data){
        this->data = data; // Save input data to node
    }
    public: Node(){

    }
    };

public: Node *first; // Beginning of the liked list
private: Node *last; // End of lined list
public: Node *Current; // current node in list


    // Constructor: clears the list and add input data
public: LinkedList(AnyType Object){
    clear();
    add(Object);
}

    // Constructor: only clears the list
public: LinkedList(){
    clear();
}

    // Method to add data to node (creates a new node and add data to it)
    // This stores the new node at the end of the list.
public: void add(AnyType Object){

    // If list is empty, create new node and set it as the first and last node in the list.
    if (isEmpty()) {
        first = new Node(Object);
        last = first;
    } else {
        // Add "after" last node
        last->next = new Node(Object);
        last = last->next;
    }

    // Sets the current node to point at the first node (just to make it easer to getNext method)
    Current = first;
}

    // Same as add but it adds the new node in the front of the list.
public: void addFirst(AnyType Object){

    // Same as add, if the list is empty:
    if (isEmpty()) {
        first = new Node(Object);
        last = first;
    } else {

        // Store the compleat list in a temp list.
        Node *temp = first;

        // Set the first node in our list to the new node
        first = new Node(Object);
        last = first;

        // Append the rest of the list (append the real list with temp list at end)
        last->next = temp;

    }
    // Sets the current node to point at the first node (just to make it easer to getNext method)
    Current = first;
}

    // Sort entire list with Bubble Sort algorithm. 
public: void bubbleSort(){

    Node *current_node;
    AnyType current_data; // Temp varible to store the nodes data

    for(int i = 1; i < size(); i++){

        current_node = first; // Copy the list to a temp list


            // Runs to end of list (as long as null does not occur)
            while (current_node->next != NULL) {

                // This is the comparing between two nodes (is current node larger than the next node?)
                if(current_node->data > current_node->next->data){

                    // Store the current node's data
                    current_data = current_node->data;

                    // Store next node's data into the current node
                    current_node->data = current_node->next->data;

                    // Store the backuped data from temp_data to the next node
                    current_node->next->data = current_data;

                    // Yes, a swap has occured


                }


                // Step forward in the list of nodes
                current_node = current_node->next;


            }
    }

}


    // Calls methods to do merge sort
public: void mergeSort(){
        first = merge_sort(first);

    }

    // Mergesort
public: Node *merge_sort (Node *right = new Node()) {


        // Check if right and right next node is null, if null -> return null
        if (right == NULL || right->next == NULL){
            return right;
        }

    Node *left = new Node();

        left = split (right); // Create a new node and call split to split right node
        right = merge_sort (right); 
        left = merge_sort (left);        

        return merge (right, left); 
    } 

    // Mergesort split
public: Node *split (Node *right = new Node()) {


        // Check if right and right next node is null, if null -> return null
        if (right == NULL || right->next == NULL){
            return NULL;
        }

        // Create new node (left), add right.next

        Node *left = new Node();

    left = right->next;

        //Node *left = right->next;
        right->next = left->next; // Assign the next node in right the value of left.next
        left->next = split (left->next); // Split nodes

        return left;
    }

    // Merge sort 
public: Node *merge (Node *right=new Node(), Node *left = new Node()) {

        // If null
        if (right == NULL){
            return left;
        }
        // If null
        if (left == NULL){
            return right;
        }

        // Compare right and left nodes data
        if (right->data < left->data) {
            right->next = merge (right->next, left);
            return right;

        } else {
            left->next = merge (right, left->next);
            return left;
        }

    } 


    // Get a node at a specific index
public: AnyType get(int index){

    // Checks index
    if(index < 0 || index >= size()){
        return NULL;
    }

    // Copy the list to a temp list
    Node *temp = first;

    // Loop to the right position in the temp list:
    for (; index > 0; index--) {
        temp = temp->next;
    }
    return temp->data;
}

    // Get the first node:
public: AnyType getFirst(){
    return first->data;
}

    // Get last node:
public: AnyType getLast(){
    return last->data;
}


public: void printAll(){

    Node * current = first;

    while (current->next != NULL) {

        cout << current->data << " ";


        current = current->next;
    }

}

    // Get the next node from list:
public: AnyType getNext(){

    // Return Null if no occurance:
    if (isEmpty()) {
        return NULL; 
    }

    // If Current node is the last node, set it to first and return it's data.
    if(Current == last){
        Current = first;
        return Current->data;

    } else {
        // If current node is not the last it will just continue and point to the next node:
        Current = Current->next;
        return Current->data;
    }
}

    // Removes the first node in the list by call to removeatIndex with param = 0;
public: void removeFirst(){
    removeatIndex(0);
}

    // Remove the last node in the list:
public: void removeLast(){
    removeatIndex(size()-1);
}


    // Remove a node at a specific index (if multiple occurrence, it will remove the first occurrence)
public: bool removeatIndex(int index){

    // Case 1: Empty list: //

    // If list is empty:
    if (first == NULL) {
        return false;
    }

    // Case 2: When removing the first node in the list //

    // If first nodes data matches the data at the specific index
    if (first->data == get(index)) {
        first = first->next; // first node i now the second node in the list

        // If first node is equal to null then the last is set to null (clear list)
        if (first == NULL) {
            last = NULL;
        }
        return true;
    }


    // Case 3: Removing a specific node in the list //
    Node *temp = first; // Copy the list to a temp list

    // Loop through the list
    while (temp->next != NULL) {

        // If match
        if (temp->next->data == get(index)) {

            Node *bort = temp->next; // Store the next node
            temp->next = bort->next; // Replace the "current" node with the node stored in bort (the node behind the node you remove)

            // If next node is the last, then set last to the info in temp
            if (bort == last) {
                last = temp;
            }
            return true;

        }else {
            // If no match, step forward in the list
            temp = temp->next;
        }
    }
    return false;
}

    // To clear this linked list
public: void clear(){
    first = NULL;
    last = NULL;
}

    // Get the current size of the list
public: int size(){
    int size = 0; 
    Node *temp = first;

    // Loop the whole list and increment a counter.
    while (temp != NULL) {
        size++;
        temp = temp->next;
    }
    return size;
}

    // Check if list is empty
    // A linked list is empty if first nod is equal to null
public: bool isEmpty(){
    return first == NULL;
}
};

And the main.cpp:

//
//  main.cpp
//  Miniprojekt 2 del 2
//
//  Created by Victor Lundgren on 2012-01-26.
//  Copyright (c) 2012 Lundgren. All rights reserved.
//

#include <iostream>
#include <fstream>
#include <time.h>
#include "LinkedListAnyType.cpp"

using namespace std;

int main (int args, char * argv[])
{    

    // Create the linked list:
    LinkedList<string> myList;

    // Timer:
    clock_t t_start, t_end;

    // Read input file:
    if (args==2) {

        // Open infile stream from argument:
        ifstream inf(argv[1]);

        // Read and add to the linked list:
        if (inf.good()) {
            while (!inf.eof()) {

                // Reading word by word:

                // Temp string
                string s;

                inf >>s;

                // Add to linked list
                myList.add(s);

                /*

                 // Reading line by line:
                 string s; // Just a temp string.

                 // Read and add each line as strings in linked list:
                 while (getline(inf, s)) {
                 myList.add(s); // Add to linked list.
                 }

                 */
            }

            inf.close();

        }

        // Do sorting, testing etc.

        cout << "\n\nReading from file: "<< argv[1];
        cout << "\nList size: "<<myList.size();
        cout << "\nUnsorted list:\n\n";
        myList.printAll();        

        cout << "\n\n... sorting ...\n";

        // Start time:
        t_start = clock();

        //myList.mergeSort();

        myList.bubbleSort();

        // End time:
        t_end = clock();

        // Time in ms:
        long millisecs = 1000*(t_end-t_start)/CLOCKS_PER_SEC;

        // Print time:
        cout << "\nOperation time: " << millisecs << " ms";

        cout << "\n\nSorted list:\n\n";
        myList.printAll();

        cout << "\n\n";
    }



    return 0;
}
share|improve this question
    
Where do you destroy the dynamically allocated objects? –  James McNellis Jan 28 '12 at 22:15
    
Oh, well I don't think I have don that :) Ho do I proceed with destroying allocated objects and where in the code would it be placed ? :) –  Victor Jan 28 '12 at 22:22

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