# How do I improve my performance with this singly linked list struct within my program?

Hey guys, I have a program that does operations of sets of strings. I have to implement functions such as addition and subtraction of two sets of strings. I need to get it down to the point where performance if of O(N+M), where N,M are sets of strings. Right now, I believe my performance is at O(N*M), since I for each element of N, I go through every element of M. I'm particularly focused on getting the subtraction to the proper performance, as if I can get that down to proper performance, I believe I can carry that knowledge over to the rest of things I have to implement.

The '-' operator is suppose to work like this, for example.

Declare set1 to be an empty set.
Declare set2 to be a set with { a b c } elements
Declare set3 to be a set with ( b c d } elements

set1 = set2 - set3

And now set1 is suppose to equal { a }. So basically, just remove any element from set3, that is also in set2.

For the addition implementation (overloaded '+' operator), I also do the sorting of the strings (since we have to).

All the functions work right now btw.

So I was wondering if anyone could

a) Confirm that currently I'm doing O(N*M) performance
b) Give me some ideas/implementations on how to improve the performance to O(N+M)

Note: I cannot add any member variables or functions to the class strSet or to the node structure.

The implementation of the main program isn't very important, but I will post the code for my class definition and the implementation of the member functions:

strSet2.h (Implementation of my class and struct)

``````// Class to implement sets of strings

// Implements operators for union, intersection, subtraction,
//  etc. for sets of strings

// V1.1 15 Feb 2011 Added guard (#ifndef), deleted using namespace RCH

#ifndef _STRSET_
#define _STRSET_

#include <iostream>
#include <vector>
#include <string>
// Deleted: using namespace std;  15 Feb 2011 RCH

struct node {
std::string s1;
node * next;
};

class strSet {

private:
node * first;

public:
strSet ();  // Create empty set
strSet (std::string s); // Create singleton set
strSet (const strSet &copy); // Copy constructor
~strSet (); // Destructor

int SIZE() const;

bool isMember (std::string s) const;

strSet  operator +  (const strSet& rtSide);  // Union
strSet  operator -  (const strSet& rtSide);  // Set subtraction
strSet& operator =  (const strSet& rtSide);  // Assignment

};  // End of strSet class

#endif  // _STRSET_
``````

strSet2.cpp (implementation of member functions)

``````#include <iostream>
#include <vector>
#include <string>
#include "strset2.h"

using namespace std;

strSet::strSet() {
first = NULL;
}

strSet::strSet(string s) {
node *temp;
temp = new node;
temp->s1 = s;
temp->next = NULL;
first = temp;
}

strSet::strSet(const strSet& copy) {
if(copy.first == NULL) {
first = NULL;
}
else {
node *n = copy.first;
node *prev = NULL;
while (n) {
node *newNode = new node;
newNode->s1 = n->s1;
newNode->next = NULL;
if (prev) {
prev->next = newNode;
}
else {
first = newNode;
}
prev = newNode;
n = n->next;
}
}
}

strSet::~strSet() {
if(first != NULL) {
while(first->next != NULL) {
node *nextNode = first->next;
first->next = nextNode->next;
delete nextNode;
}
}
}

int strSet::SIZE() const {
int size = 0;
node *temp = first;
while(temp!=NULL) {
size++;
temp=temp->next;
}
return size;
}

bool strSet::isMember(string s) const {
node *temp = first;
while(temp != NULL) {
if(temp->s1 == s) {
return true;
}
temp = temp->next;
}
return false;
}

strSet strSet::operator +  (const strSet& rtSide) {
strSet newSet;
newSet = *this;
node *temp = rtSide.first;
while(temp != NULL) {
string newEle = temp->s1;
if(!isMember(newEle)) {
if(newSet.first==NULL) {
node *newNode;
newNode = new node;
newNode->s1 = newEle;
newNode->next = NULL;
newSet.first = newNode;
}
else if(newSet.SIZE() == 1) {
if(newEle < newSet.first->s1) {
node *tempNext = newSet.first;
node *newNode;
newNode = new node;
newNode->s1 = newEle;
newNode->next = tempNext;
newSet.first = newNode;
}
else {
node *newNode;
newNode = new node;
newNode->s1 = newEle;
newNode->next = NULL;
newSet.first->next = newNode;
}
}
else {
node *prev = NULL;
node *curr = newSet.first;
while(curr != NULL) {
if(newEle < curr->s1) {
if(prev == NULL) {
node *newNode;
newNode = new node;
newNode->s1 = newEle;
newNode->next = curr;
newSet.first = newNode;
break;
}
else {
node *newNode;
newNode = new node;
newNode->s1 = newEle;
newNode->next = curr;
prev->next = newNode;
break;
}
}
if(curr->next == NULL) {
node *newNode;
newNode = new node;
newNode->s1 = newEle;
newNode->next = NULL;
curr->next = newNode;
break;
}
prev = curr;
curr = curr->next;
}
}
}
temp = temp->next;
}
return newSet;
}

strSet strSet::operator - (const strSet& rtSide) {
strSet newSet;
newSet = *this;
node *temp = rtSide.first;
while(temp != NULL) {
string element = temp->s1;
node *prev = NULL;
node *curr = newSet.first;
while(curr != NULL) {
if( element < curr->s1 ) break;
if( curr->s1 == element ) {
if( prev == NULL) {
node *duplicate = curr;
newSet.first = newSet.first->next;
delete duplicate;
break;
}
else {
node *duplicate = curr;
prev->next = curr->next;
delete duplicate;
break;
}
}
prev = curr;
curr = curr->next;
}
temp = temp->next;
}
return newSet;
}

strSet& strSet::operator =  (const strSet& rtSide) {
if(this != &rtSide) {
if(first != NULL) {
while(first->next != NULL) {
node *nextNode = first->next;
first->next = nextNode->next;
delete nextNode;
}
}
if(rtSide.first == NULL) {
first = NULL;
}
else {
node *n = rtSide.first;
node *prev = NULL;
while (n) {
node *newNode = new node;
newNode->s1 = n->s1;
newNode->next = NULL;
if (prev) {
prev->next = newNode;
}
else {
first = newNode;
}
prev = newNode;
n = n->next;
}
}
}
return *this;
}
``````
-
Rob's right. Basically any operation of this type can be done in linear time if the lists are ordered. It's the general merge algorithm. –  Mike Dunlavey Mar 17 '11 at 1:31

Yes, I believe your current `operator-` is O(N*M).
re: homeowrk. Sorry, when I read "our prof wanted a very simple implementation of a linked list", I assumed you were doing this at school at the request of a professor. I'll delete the 'homework' tag I added. You can write O(N+M) algorithm by walking the two lists in parallel. `new=empty; while(lhs != end && rhs != end) { if (*lhs == *rhs) { ++lhs, ++rhs } elsif (*lhs < *rhs) { new.add(*lhs++); } else { rhs++ } } // then copy remaining items from rhs or lhs to new` –  Robᵩ Mar 17 '11 at 0:19
@Jesus: Rob Adams has a linear algorithm in his comment. He's basically recreated `std::set_difference` from the standard library. –  Blastfurnace Mar 17 '11 at 0:56