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:

- The index passed to the operator[] corresponds to the power of X whose coefficient we want to modify / read.
- 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. - 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!