i write matrix class in c++ and overloaded some operator like = and >> and << ,... but i can't overloading operator [][] for matrix class. if i have an object of class matrix like M1 then i can use this way for giving value to each element:

M1[1][2]=5;

OR

int X;

X=M1[4][5];
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–  Jerry Coffin Apr 12 '11 at 14:53

Just overload operator[] and make it return a pointer to the respective row or column of the matrix. Since pointers support subscripting by [], access by the 'double-square' notation [][] is possible then.

You can also overload operator() with two arguments.

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I prefer RedX's solution over this one because in my opinion you should not use pointers in C++ unless you absolutely have to. –  Björn Pollex Apr 12 '11 at 14:56
I find that operator(x,y) is a good solution in such circumstances. –  edA-qa mort-ora-y Apr 12 '11 at 14:59

There is no operator[][] in C++. You have to return a helper object and then overload operator[] for that too, to have this kind of access.

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You could overload operator[]. So if you would like to use matrix that way, you should make matrix as array of vectors.

class Matrix
{
...
Vector & operator[]( int index );
...
};

and

class Vector
{
...
double & operator[]( int index );
...
};

Finally:

Matrix m;
...
double value = m[i][j];
...
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there is no operator[][], you can implement operator[] to return a reference to the row/column object, in which you can implement the operator[] to return you the cell reference.

You can do something like the following to avoid all that hassle..

struct loc
{
int x;
int y;
};

T& operator[](loc const& cLoc)
{
// now you have x/y you can return the object there.
}

To call, you can simply do something like:

matrix[loc(2,3)] = 5;
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This is an interesting idea I haven't seen before, but is still immediately obvious what it does. –  David Stone Feb 8 '14 at 17:31

You can't overload [][] as such, since there isn't such an operator. You can overload [] to return something which also has an [] defined on it (a proxy); in the simplest case, something like a double* will work, but it's usually better, although a bit more work, to use a full class. (Place to add bounds checking, for example.)

Alternatively, you can overload (x,y). Depending on who you ask, one format or the other is "better". (In fact, it's strictly a question of style.)

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Actually, I did just that in my own matrix class a few years ago. In this case, I defined a matrix template class that contained the snippet, below.

I was then able to iterate and assign as follows:

for(size_t k=1; k<n; ++k) {
minor[p][k-1]=major[j][k];
}

I hope this helps.

// //////////////////////////////////////////////////////////////////////////////
// list is internal vector representation of n x m matrix
T* list;
// Proxy object used to provide the column operator
template < typename T >
class OperatorBracketHelper
{
Matrix < T > & parent ;
size_t firstIndex ;

public :
OperatorBracketHelper ( Matrix < T > & Parent , size_t FirstIndex ) :
parent ( Parent ), firstIndex ( FirstIndex ) {}

// method called for column operator
T & operator []( size_t SecondIndex )
{
// Call the parent GetElement method which will actually retrieve the element
return parent.GetElement ( firstIndex , SecondIndex );
}
};

// method called for row operator
OperatorBracketHelper < T > operator []( size_t FirstIndex )
{
// Return a proxy object that "knows" to which container it has to ask the element
// and which is the first index (specified in this call)
return OperatorBracketHelper < T >(* this , FirstIndex );
}

T & GetElement ( size_t FirstIndex , size_t SecondIndex )
{
return list[FirstIndex*cols+SecondIndex];
}
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