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I am writing a template `Polynom<T>` class where `T` is the numeric type of its coefficients.

The coefficients of the polynom are stored in an `std::vector<T> coefficients`, where `coefficients[i]` corresponds to `x^i` in a real polynom. (so the powers of x are in increasing order).

It is guaranteed that `coefficients` vector always contains at least one element. - for a zero polynom it is `T()`.

I want to overload the `operator[]` to do the following:

1. The index passed to the operator[] corresponds to the power of X whose coefficient we want to modify / read.
2. If the user wants to just read the coefficient, it should throw for negative indices, return `coefficients.at(i)` for indices within the stored range - and reasonably return 0 for all other indices, not throw.
3. If the user wants to modify the coefficient, it should throw for negative indices, but let user modify all other indices freely, even if the index specified is bigger than or equal to `coefficients.size()`. So we want to somehow resize the vector.

The main problem I have collided with is as follows:

1.

How do I distinguish between the read case and the write case? One person left me without an explanation but said that writing two versions:

``````const T& operator[] (int index) const;
T& operator[] (int index);
``````

was insufficient. However, I thought that the compiler would prefer the const version in the read case, won't it?

2.

I want to make sure that no trailing zeros are ever stored in the `coefficients` vector. So I somehow have to know in advance, "before" I return a mutable `T&` of my coefficient, what value user wants to assign. And I know that `operator[]` doesn't receive a second argument.

Obviously, if this value is not zero (not T()), then I have to resize my vector and set the appropriate coefficient to the value passed.

But I cannot do it in advance (before returning a `T&` from `operator[]`), because if the value to be assigned is T(), then, provided I resize my coefficients vector in advance, it will eventually have lots of trailing "zeroes".

Of course I can check for trailing zeroes in every other function of the class and remove them in that case. Seems a very weird decision to me, and I want every function to start working in assumption that there are no zeroes at the end of the vector if its size > 1.

Could you please advise me as concrete solution as possible to this problem? I heard something about writing an inner class implicitly convertible to `T&` with overloaded `operator=`, but I lack the details.

Thank you very much in advance!

-

One option you could try (I haven't tested this):

``````template<typename T>
class MyRef{
private:
int index;
Polynom<T>*p;
public:
MyRef(int index, Polynom<T>*p) : index(index), p(p) { }

MyRef<T>& operator=(T const&t); //and define these appropriately
T operator T() const;
};
``````

and define:

``````    MyRef<T> operator[](int index){
return MyRef<T>(index, this);
}
``````

This way when you assign a value to the "reference" it should have access to all the needed data in the polynomial, and take the appropriate actions.

I am not familiar enough with your implementation, so I'll instead give an example of a very simple dynamic array that works as follows:

• you can read from any `int index` without concern; elements not previously written to should read off as `0`;
• when you write to an element past the end of the currently allocated array, it is reallocated, and the newly allocated elements are initialized to `0`.
``````#include <cstdlib>
#include <iostream>
using namespace std;

template<typename T>
class my_array{
private:
T* _data;
int _size;

class my_ref{

private:
int index;
T*& obj;
int&size;
public:
my_ref(T*& obj, int&size, int index)
: index(index), obj(obj), size(size){}

my_ref& operator=(T const& t){

if (index>=size){
obj = (T*)realloc(obj, sizeof(T)*(index+1) );
while (size<=index)
obj[size++]=0;
}
obj[index] = t;

return *this;
}

//edit:this one should allow writing, say, v[1]=v[2]=v[3]=4;
my_ref& operator=(const my_ref&r){
operator=( (T) r);
return *this;
}

operator T() const{
return (index>=size)?0:obj[index];
}

};

public:
my_array() : _data(NULL), _size(0) {}

my_ref operator[](int index){
return my_ref(_data,_size,index);
}

int size() const{ return _size; }

};

int main(){

my_array<int> v;

v[0] = 42;
v[1] = 51;
v[5] = 5; v[5]=6;
v[30] = 18;

v[2] = v[1]+v[5];
v[4] = v[8]+v[1048576]+v[5]+1000;

cout << "allocated elements: " <<  v.size() << endl;
for (int i=0;i<31;i++)
cout << v[i] << " " << endl;

return 0;
}
``````

It's a very simple example and not very efficient in its current form but it should prove the point.

Eventually you might want to overload `operator&` to allow things like `*(&v[0] + 5) = 42;` to work properly. For this example, you could have that `operator&` gives a `my_pointer` which defines `operator+` to do arithmetic on its `index` field and return a new `my_pointer`. Finally, you can overload `operator*()` to go back to a `my_ref`.

-
Thank you! Could you please also clarify the following: 1. Should I make this class inner & private? 2. Can I return a reference to an instance of a private class? – wh1t3cat1k Nov 9 '11 at 9:40
I've updated my example to use a private nested class. It still works (see: ideone.com/dRr4D) but I haven't used nested classes too much in the past so I don't know what the best practices are. – Vlad Nov 9 '11 at 9:52
This won't cover use cases such as `int &r = v[1]; r = 3;`. – Oliver Charlesworth Nov 9 '11 at 10:27
True, there are limitations. But you can always (assuming `my_ref` were public) use `my_array<int>::my_ref r = v[1]; r= 3;` if necessary. – Vlad Nov 9 '11 at 10:33

The solution to this is a proxy class (untested code follows):

``````template<typename T> class Polynom
{
public:
class IndexProxy;
friend class IndexProxy;
IndexProxy operator[](int);
T operator[](int) const;
// ...
private:
std::vector<T> coefficients;
};

template<typename T> class Polynom<T>::IndexProxy
{
public:
friend class Polynom<T>;
// contrary to convention this assignment does not return an lvalue,
// in order to be able to avoid extending the vector on assignment of 0.0
T operator=(T const& t)
{
if (theIndex >= thePolynom.coefficients.size())
thePolynom.coefficients.resize(theIndex+1);
thePolynom.coefficients[theIndex] = t;
// the assignment might have made the polynom shorter
// by assigning 0 to the top-most coefficient
while (thePolynom.coefficients.back() == T())
thePolynom.coefficients.pop_back();
return t;
}
operator T() const
{
if (theIndex >= thePolynom.coefficients.size())
return 0;
return thePolynom.coefficients[theIndex];
}
private:
IndexProxy(Polynom<T>& p, int i): thePolynom(p), theIndex(i) {}
Polynom<T>& thePolynom;
int theIndex;
}

template<typename T>
Polynom<T>::IndexProxy operator[](int i)
{
if (i < 0) throw whatever;
return IndexProxy(*this, i);
}

template<typename T>
T operator[](int i)
{
if (i<0) throw whatever;
if (i >= coefficients.size()) return T();
return coefficients[i];
}
``````

Obviously the code above is not optimized (especially the assignment operator has clearly room for optimization).

-
+1. May I ask you to clarify why you chose to not make `operator=` return an lvalue? I'm trying to think of possible problems when it does return a `&` but I can't think of any right now. – Vlad Nov 9 '11 at 10:08
Returning T& would have implied to have an object to bind it to, which might not exist in the case of assigning 0. As I only now notice, I could also have returned a reference to IndexProxy itself. But the only extra code that enables would be of the form you wouldn't want to write anyway; the code which you might want to write (binding the result of the assignment expression to a reference to T) would still not work. – celtschk Nov 9 '11 at 13:12
Thank you for answering. As for the last part, you're right, it didn't work, I added another overload for the `operator=` to make that case work. – Vlad Nov 9 '11 at 13:56

You cannot distinguish between read and write with operator overloads. The best you can do is distinguish between usage in a `const` setting and a non-`const` setting, which is what your code snippet does. So:

``````Polynomial &poly = ...;

poly[i] = 10;  // Calls non-const version
int x = poly[i];  // Calls non-const version

const Polynomial &poly = ...;

poly[i] = 10;   // Compiler error!
int x = poly[i]  // Calls const version
``````

It sounds like the answer to both your questions, therefore, is to have separate `set` and `get` functions.

-

I see two solutions to your problem:

1. Instead of storing the coefficients in a `std::vector<T>` store them in a `std::map<unsigned int, T>`. This way you will ever only store non-zero coefficients. You could create your own `std::map`-based container that would consume zeros stored into it. This way you also save some storage for polynomials of the form x^n with large n.

2. Add an inner class that will store an index (power) and coefficient value. You would return a reference to an instance of this inner class from `operator[]`. The inner class would overwrite `operator=`. In the overridden `operator=` you would take the index (power) and coefficient stored in inner class instance and flush them to the `std::vector` where you store your coefficients.

-
`std::map` also stores zero elements. Moreover, if you ask it for an element it does not yet contain, it creates is with the value zero. For example: `std::map<int,int> m; int k=m[1]; k=m[3]; std::cout << m.size();` prints 2, because now there are two key-value pairs in the map: (1,0) and (3,0). – celtschk Nov 9 '11 at 13:16
That's right. Corrected. Thanks! – Adam Zalcman Nov 9 '11 at 13:42

This is not possible. The only way I can think of is to provide a special member-function for adding new coefficients.

The compiler decides between the `const` and non-`const` version by looking at the type of `Polynom`, and not by checking what kind of operation is performed on the return-value.

-