# How to implement polynomial class using linked list and monomial class C++

So I need to create two classes one for Monomials. The other for polynomials (built using a linked list of Monomials).

I have the function declarations done and now I need to get into the definitions, which is where I'm stuck.

I think if I can get some direction on one function I'll be able to write the rest. Here is the direction I'm going with it, not sure if this is right. If it isn't can you point me in the right direction? Never used a the iterator thing so that's really throwing me off. Here is my header

``````#ifndef __POLYNOMIAL_H_
#define __POLYNOMIAL_H_

#include <iostream>
#include <list>
#include "Polynomial.cpp"

#define var = 'x' //varible to use in polynomial

using namespace std;

struct ZERO_T {
static const short ZERO = 0;
};
template <typename NumT>
class Monomial
{
public:
Monomial<NumT>(NumT c = 0, int d = 0) : coeff(c), expo(d)
{ };
NumT coefficient(void) const { return coeff; };
int degree(void) const { return expo; };
void assign_coefficient(const NumT c) { coeff = c; };
void assign_degree(const int d) { expo = d; };
bool operator==(const Monomial<NumT> & m) const
{
return (coeff == m.coeff && expo == m.expo);};
bool operator!=(const Monomial<NumT> & m) const
{return (coeff != m.coeff || expo != m.expo);};

private:
NumT coeff;
int expo;
};
template <typename NumberType>
class Polynomial : public ZERO_T
{
public:
Polynomial<NumberType>(NumberType c = 0, int d = 0)
{
const Monomial<NumberType> m(c, d);
term_list.push_back(m); //creates a ZERO monomial
number_of_terms = 1;
highest_degree = d;
}

Polynomial<NumberType>(const Monomial<NumberType> & m) //type conversion constructor
{
term_list.push_back(m);
number_of_terms = 1;
highest_degree = m.degree();
}

~Polynomial<NumberType>() { } // use default destructors and list's destructor

Polynomial<NumberType>(const Polynomial<NumberType> & rhs) // copy constructor
: term_list(rhs.term_list), number_of_terms(rhs.number_of_terms),
highest_degree(rhs.highest_degree) { }

const Polynomial<NumberType> & operator=(const Polynomial<NumberType> & rhs);
//copy assignment
Polynomial<NumberType> operator+=(const Monomial<NumberType> &m);
Polynomial<NumberType> operator+=(const Polynomial<NumberType> & rhs);
const Polynomial<NumberType> operator+(const Monomial<NumberType> &m)const;
const Polynomial<NumberType> operator+(const Polynomial<NumberType> & rhs) const;
Polynomial<NumberType> operator*=(const Monomial<NumberType> &m);
Polynomial<NumberType> operator*=(const Polynomial<NumberType> & rhs);
const Polynomial<NumberType> operator*(const Monomial<NumberType>  &m) const;
const Polynomial<NumberType> operator*(constPolynomial<NumberType> & rhs) const;
const NumberType evaluate(NumberType x);
bool operator==(const Polynomial<NumberType> &p) const;
bool operator!=(const Polynomial<NumberType> &p) const;
const int gethighestdegree();
void read(istream & in = cin);
void print(ostream & out = cout) const;
//static Polynomial<NumberType> ZERO;
private:
list<Monomial<NumberType> > term_list;
//sorted by decreasing degrees
int number_of_terms;
int highest_degree;
void insert_in_poly(Polynomial<NumberType> & p, const Monomial<NumberType> & m);
//helper function
NumberType power(NumberType x, int n);
};
//template<> Polynomial<int> Polynomial<int>::ZERO = 0;
template <typename NumberType>
istream&operator>>(istream &  in, Polynomial<NumberType> & rhs);

template <typename NumberType>
ostream& operator<<(ostream & out, const Polynomial<NumberType> & rhs);

#include "polynomial.cpp"
#endif
``````

How would you do the add? Here's what I have so far:

``````#ifndef __POLYNOMIAL_CPP_
#define __POLYNOMIAL_CPP_

#include <iostream>
#include <cmath>
#include <list>
#include "polynomial.h"
#endif

template<typename NumberType>
const Polynomial<NumberType> Polynomial<NumberType>::operator+(const Monomial<NumberType>& m) const
{
int i = 0;
term_list.sort();  //sort list in decending order
term_list.reverse();  //rearrange into ascending order
Monomial temp;      //create a temp object to hold our monomial
temp.coeff = m.coeff;
temp.expo = m.expo;
/////////////////experiments here/////////
list <Monomial<NumberType>>::iterator itr;
itr = p.termlist.begin();
while (itr != p.termlist.end())       //traverse termlist until we reach end
{
if (itr.expo == temp.expo)      //if temp exponents meet current list exponent
itr insert(i, NumberType& temp);        //insert monomial here
else
i++;
}
``````

Obviously I still need to doctor it up with what if the list is empty and what if the exponent match is never found and such. But for now I just want a simple add monomial to polynomial function to use as an example to build my other functions please.

• A `list`! Praise all that is holy, the OP is allowed to use a `list`! But trust me on this. I'm being serious now. You do not want to include a cpp file. Ever. Especially not in a header. Only pain will come of it. And while we are on the subject of pain, remove `using namespace std;` from the header. `using namespace std;` is like a bomb. You have to be cautious about how and where you use it because if you don't you have lot of clean-up to do when it goes off. Oct 6, 2015 at 3:19
• On to the question. Add an `operator+` to your monomial class. Then you should be able to add monomials of the same order with simple arithmetic as you iterate through the the polynomial's monomials. Oct 6, 2015 at 3:24
• @user4581301, why don't you write an answer? Oct 6, 2015 at 3:50

After looking at your classes declarations I can see some issues and will try to mark up your existing code with comments to help you out. I will also suggest that since your classes are templates you should have 3 files to the class: `ClassName.h`, `ClassName.inl` & `ClassName.cpp` this will help you in the long run due to the behavior of templates. After making comments in your standing code I will then try to reconstruct your classes as they would appear in their respective files.

This Is What You Have

``````#ifndef __POLYNOMIAL_H_
#define __POLYNOMIAL_H_

#include <iostream>
#include <list>
#include "Polynomial.cpp" // Why including *.cpp?

#define var = 'x' //varible to use in polynomial

using namespace std;

struct ZERO_T {
static const short ZERO = 0;
};

template <typename NumT>
class Monomial {
public:
Monomial<NumT>(NumT c = 0, int d = 0) : coeff(c), expo(d)
{ };
NumT coefficient(void) const { return coeff; };
int degree(void) const { return expo; };
void assign_coefficient(const NumT c) { coeff = c; };
void assign_degree(const int d) { expo = d; };
bool operator==(const Monomial<NumT> & m) const
{
return (coeff == m.coeff && expo == m.expo);};
bool operator!=(const Monomial<NumT> & m) const
{return (coeff != m.coeff || expo != m.expo);};

private:
NumT coeff;
int expo;
};

template <typename NumberType>
class Polynomial : public ZERO_T {
public:
Polynomial<NumberType>(NumberType c = 0, int d = 0) {
const Monomial<NumberType> m(c, d);
term_list.push_back(m); //creates a ZERO monomial
number_of_terms = 1;
highest_degree = d;
}

Polynomial<NumberType>(const Monomial<NumberType> & m) //type conversion constructor {
term_list.push_back(m);
number_of_terms = 1;
highest_degree = m.degree();
}

~Polynomial<NumberType>() { } // use default destructors and list's destructor

Polynomial<NumberType>(const Polynomial<NumberType> & rhs) // copy constructor
: term_list(rhs.term_list), number_of_terms(rhs.number_of_terms),
highest_degree(rhs.highest_degree) { }

const Polynomial<NumberType> & operator=(const Polynomial<NumberType> & rhs);
//copy assignment
Polynomial<NumberType> operator+=(const Monomial<NumberType> &m);
Polynomial<NumberType> operator+=(const Polynomial<NumberType> & rhs);
const Polynomial<NumberType> operator+(const Monomial<NumberType> &m)const;
const Polynomial<NumberType> operator+(const Polynomial<NumberType> & rhs) const;
Polynomial<NumberType> operator*=(const Monomial<NumberType> &m);
Polynomial<NumberType> operator*=(const Polynomial<NumberType> & rhs);
const Polynomial<NumberType> operator*(const Monomial<NumberType>  &m) const;
const Polynomial<NumberType> operator*(constPolynomial<NumberType> & rhs) const;
const NumberType evaluate(NumberType x);
bool operator==(const Polynomial<NumberType> &p) const;
bool operator!=(const Polynomial<NumberType> &p) const;
const int gethighestdegree();
void read( istream & in = cin );
void print( ostream & out = cout ) const;
//static Polynomial<NumberType> ZERO;
private:
list<Monomial<NumberType> > term_list;
//sorted by decreasing degrees
int number_of_terms;
int highest_degree;
void insert_in_poly(Polynomial<NumberType> & p, const Monomial<NumberType> & m);
//helper function
NumberType power( NumberType x, int n );
};

//template<> Polynomial<int> Polynomial<int>::ZERO = 0;
template <typename NumberType>
istream& operator>>( istream &  in, Polynomial<NumberType> & rhs );

template <typename NumberType>
ostream& operator<<( ostream & out, const Polynomial<NumberType> & rhs );

#include "polynomial.cpp" // Why include *.cpp?
#endif
``````

I will try to simplify your classes for easier reading while separating the declarations from the definitions.

Monomial.h

``````#ifndef MONOMIAL_H
#define MONOMIAL_H

template<typename NumT>
class Monomial {
private:
NumT m_coeff;
int  m_expo;

public:
explicit Monomial( NumT c = 0, int d = 0 ); // Added Explicit since both parameters can be defaulted

NumT coefficient() const;
int  degree() const;

void assignCoefficient( const NumT c );
void assignDegree( const int d );

bool operator==( const Monomial<NumT>& other ) const;
bool operator!=( const Monomial<NumT>& other ) const;

private:
Monomial( const Monomial& c ); // Not Implemented - Copy Constructor
Monomial& operator=( const Monomial& c ); // Not Implemented - Assignment Operator

}; // Monomial

#include "Monomial.inl"

#endif // MONOMIAL_H
``````

Monomial.inl

``````// -------------------------------------------------------------------------
// Monomial() - Constructor
template<typename NumT>
Monomial<NumT>::Monomial( NumT c, int d ) :
m_coeff( c ),
m_expo( d ) {
} // Monomial

// -------------------------------------------------------------------------
// coefficient()
template<typename NumT>
NumT Monomial<NumT>::coefficient() const {
return m_coeff;
} // coefficient

// -------------------------------------------------------------------------
// degree()
template<typename NumT>
int Monomial<NumT>::degree() const {
return m_expo;
} // degree

// -------------------------------------------------------------------------
// assignCoefficient()
template<typename NumT>
void Monomial<NumT>::assignCoefficient( const NumT c ) {
m_coeff = c;
} // assignCoefficient

// -------------------------------------------------------------------------
// assignDegree()
template<typename NumT>
void Monomial<NumT>::assignDegree( const int d ) {
m_expo = d;
} // assignDegree

// -------------------------------------------------------------------------
// operator==()
template<typename NumT>
bool Monomial<NumT>::operator==( const Monomial<NumT>& other ) const {
return ( m_coeff == other.m_coeff && m_expo == other.m_expo );
} // operator==

// -------------------------------------------------------------------------
// operator!=()
template<typename NumT>
bool Monomial<NumT>::operator!= ( const Monomial<NumT>& other ) const {
return ( m_coeff != other.m_coeff || m_expo != other.m_expo );
} // operator!=
``````

Monomial.cpp

``````#include "Monomial.h"
``````

Polynomial.h

``````#ifndef POLYNOMIAL_H
#define POLYNOMIAL_H

#include <iostream>
#include <list>

#include "Monomial.h"

#define var = 'x'

struct ZERO_T {
static const short ZERO = 0;
};

template<typename NumberType>
class Polynomial : public ZERO_T {
friend std::istream& operator>>( std::istream& in, const Polynomial<NumberType>& poly );
friend std::ostream& operator<<( std::ostream& out, const Polynomial<NumberType>& poly );
private:
list<Nomomial<NumberType>> m_lTerms;

int m_iNumTerms;
int m_iHighestDegree;

public:
// Constructors & Destructors
explicit Polynomial( NumberType c = 0, int d = 0 );
Polynomial( const Monomial<NumberType>& m );
Polynomial( const Polynomial<NumberType& rhs );
// ~Polynomial(); // Default Okay

// Assignment Operator
const Polynomial<NumberType>& operator=( const Polynomial<NumberType>& rhs );

// Comparison Operators
bool operator==( const Polynomial<NumberType>& p ) const;
bool operator!=( const Polynomial<NumberType>& p ) const;
bool operator<(  const Polynomial<NumberType>& p ) const;
bool operator<=( const Polynomial<NumberType>& p ) const;
bool operator>(  const Polynomial<NumberType>& p ) const;
bool operator>=( const Polynomial<NumberType>& p ) const;

// Numerical Operators
Polynomial<NumberType>& operator+=( const Monomial<NumberType>& m );
Polynomial<NumberType>& operator+=( const Polynomial<NumberType>& rhs );
Polynomial<NumberType>  operator+(  const Monomial<NumberType>& m ) const;
Polynomial<NumberType>  operator+(  const Polynomial<NumberType>& rhs ) const;
Polynomial<NumberType>& operator*=( const Monomial<NumberType>& m );
Polynomial<NumberType>& operator*=( const Polynomial<NumberType>& rhs );
Polynomial<NumberType>  operator*(  const Monomial<NumberType>& m ) const;
Polynomial<NumberType>  operator*(  const Polynomial<NumberType& rhs ) const;

// Public Member Functions
int getHighestDegree() const;

void read( std::istream& in = cin );
void print( std::ostream& out = cout ) const;

private:
void insertInPoly( Polynomial<NumberType>& p; const Monomial<NumberType>& m );
NumberType power( NumberType x, int n );

}; // Polynomial

#include "Polynomial.inl"

#endif // POLYNOMIAL_H
``````

Polynomial.inl

``````// -------------------------------------------------------------------------
// Polynomial()

// To save some time all of this class's implementations should be in here
// where template<typename T> needs to be defined, just as I did within
// Monomial.inl
``````

Polynomial.cpp

``````#include "Polynomial.h"
``````

This style of layout separates the declarations from the definitions making the code easier to read and allowing it to be modular. This way a person or user who is using your classes doesn't have to worry about how these functions work they only need to see the declaration of what they return and what parameters they accept with a basic description of what kind of tasks the functions / methods perform. I also removed some lines of code that were not needed in the Monomial class since they were only being used by the Polynomial class `#includes`, `#defines` & `structure` and moved them into the Polynomial class where they are needed.

If you are creating a stack variable of type Monomial called temp you need to use the template brackets for the variable as such:

``````Monomial<NumberType> temp; // You did define Monomial as a template type.
``````

I see that you are setting both the coefficient & exponent of your passed in parameter of a Monomial<> type, it could be helpful to define the assignment operator in your Monomial class. You may want to also add other operators to your Monomial Class as well +, +=, *, *=, etc.

You have to remember that the numerical operators in your Polynomial are for adding & multiplying two Polynomials together. If you are trying to add two Monomials together then this is where you will need the operator in your Monomial class.

• Glad you covered all that, Francis. Meant I didn't have to and could stick to the code. Probably saved me half an hour. Thanks! Oct 6, 2015 at 6:16
• Not a problem! Helping others also helps me to improve my own skills. I am also self taught with no formal training or any college classes, I had to learn the hard way by doing millions of searches across the web long before any video tutorials came out, and everything the text sites showed nothing would ever seem to compile, build, link or run properly and most of these sites never give any tips or hints about the debugger, linker warnings and errors. I've learned a lot on my own, but if I can spare inexperienced people that trouble by pointing them in the right direction, its all the better! Oct 6, 2015 at 7:20
• Another tip would be to define macros for variables such as `#define var = 'x'` and replace it with `static const char x;` in your header file and in your cpp file `const char x = 'x';` It doesn't have to be static; but this is how I usually structure any type of global variable that is specific to a class type or a group of class types. Oct 7, 2015 at 18:00

Why I don't like answering questions like this: In order to answer it you wind up doing half of someone's homework. Maybe they learn, maybe they don't, but lemme tell ya something. Cut and paste may get you through a class, but it leave you serving coffee and selling phones in real life.

I'm not even trying to optimize this code. The polynomial += polynomial operator is the worst way to do it. It is also the fastest to write.

OK. The Monomial class is largely the same. I add two methods and a friend function.

``````Monomial& operator+=(const Monomial & toadd)
{
{
throw "Mismatched exponents";
}
return *this;
}
``````

Pretty simple. If the coefficients don't match, blow up. Otherwise add the coefficients and return a reference to the modified object.

I start with += because + is += called with a local copy

``````Monomial operator+(const Monomial & toadd) const
{
}
``````

I toyed with passing in non const non reference toadd because somebody's getting copied, but wimped out and went for the familiar. I don't play games with the return because it is a trivial object to copy and any constructor logic will probably be elided if the compiler sees a need.

``````friend std::ostream& operator<<(std::ostream & out,
const Monomial<NumT> & rhs)
{
out << rhs.coeff << '^' << rhs.expo;
return out;
}
``````

And a standard << override to test the results.

The Polynomial class I write entirely inside the class. There is usually nothing to be gained from spinning off the implementation of a template and this is no exception.

``````Polynomial & operator+=(const Monomial<NumberType> &m)
{
auto found = std::find_if(term_list.begin(),
term_list.end(),
[&m] (const Monomial<NumberType> &mono)
{
return mono.degree() == m.degree();
} );
if (found != term_list.end())
{
*found += m;
}
else
{
term_list.push_back(m);
highest_degree = std::max(m.degree(), highest_degree);
number_of_terms++; // pointless variable. Should always equal term_list.size()
}
return *this;
}
``````

I got rid of the sorting. There's not much point to sorting and resorting every time. Sorting every time is an O(n) that you're probably going to have to do anyway since Polynomial is built around std::list. Sort when the list is modified or don't sort at all. Anyway, I used std::find_if, which may have some container and ordering optimizations baked in, to do the look-up if the container is changed in the future.

``````Polynomial & operator+=(const Polynomial & rhs)
{
for (auto & mono: rhs.term_list)
{
*this += mono;
}
return *this;
}
``````

This is the laziest, stupidest way I could add two polynomials. Every monomial in rhs is added to `this`. Since polynomial + monomial inserts exponents that aren't there and adds to those that are, all monomials will be represented in the result. I'm pretty sure the time complexity can be reduced from O(n^2) to O(n) with some care and attention.

``````const Polynomial operator+(const Monomial<NumberType> &m) const
{
return Polynomial (*this) += m;
}

const Polynomial operator+(const Polynomial & rhs) const
{
return  Polynomial (*this) += rhs;
}
``````

Same as last time the operator + simply copies and calls +=.

``````friend std::ostream& operator<<(std::ostream & out,
const Polynomial<NumberType> & rhs)
{
if (!rhs.term_list.empty())
{
auto mono = rhs.term_list.begin();
out << *mono;
for (++mono; mono != rhs.term_list.end();++mono)
{
out << " + " << *mono;
}
}
else
{
out << "empty";
}
return out;
}
``````

And again a << overload for easy testing.

Finally some test code to make sure I'm not totally on crack.

``````#include <iostream>
#include "Polynomial.h"
using namespace std;

int main()
{
Polynomial<int> p;

p += Monomial<int>(100,0);
p += Monomial<int>(1,1);
p += Monomial<int>(0,2);
p += Monomial<int>(1,3)+Monomial<int>(1,3);
p += Monomial<int>(5,4);
cout << p<<endl;

auto p2 = p+ Monomial<int>(3,3);
cout << p2 << endl;
cout << p+p2<< endl;
}
``````
• My answer addressed the poor layout of the askers question so I gave an elegant example of what the class ought to look like and addressed what they could do to write the code to perform their tasks or work while trying to point them in the right direction. However, your answer gives them the complete break down of the algorithm needed to do so. I do like how you explained the time variances of different methods between sorting, swapping, comparing etc. Very few are willing to go to that length unless they are explicitly asked to do so. :) Oct 6, 2015 at 7:36
• I covered the poor formatting and you covered the algorithm nice team work! Oct 6, 2015 at 7:41