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I'm still new to C++ so I daily run into new problems.

Today came the [] operator's turn:

I'm making myself a new generic List class because I don't really like the std's one. I'm trying to give it the warm and fuzzy look of the C#'s Collections.Generic List, so I do want to be able to access elements by index. To cut to the chase:

Extract from the template:

T& operator[](int offset)
        int translateVal = offset - cursorPos;


        return cursor->value;

    const T& operator[](int offset) const
        int translateVal = offset - cursorPos;


        return cursor->value;

That's the code for the operators. The template uses "template", so as far as I saw on some tutorials, that's the correct way to do operator overloading.

Nevertheless, when I'm trying to access by index, e.g.:

Collections::List<int> *myList;
myList = new Collections::List<int>();
int a = myList[0];

I get the

    no suitable conversion function from "Collections::List<int>" to "int" exists

error, referring to the "int a = myList[0]" line. Basically "myList[0]" type's is still "Collections::List", although it should have been just int. How Come?

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up vote 14 down vote accepted

Since myList is a pointer myList[0] doesn't invoke operator[], it returns Collections::List<int>*. What you want is (*myList)[0]. Or better still, Collections::List<int>& myRef = *myList; and then use myRef[0] (Other option is not allocate the memory for myList on the heap, you can create it on stack using Collections::List<int> myList and then use . operator on it).

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Good point actually. In my case I just changed the list declaration, cutting out the pointer part. That was it, thanks! – cantrem Feb 24 '11 at 9:58
@cantrem: in C++, you should not use allocation with new if you can avoid it. Since there is no garbage collector, you will have to manually delete those objects, which can became quite a pain when your project starts growing and you always have to know who "owns" the object and is responsible for deleting it. – Mephane Feb 24 '11 at 10:15
Yes and no. Although not set by default, there are a couple of smart pointers out there to help you take out the garbage. – cantrem Feb 24 '11 at 10:53

myList has type pointer to List, not List. In the case where an expression of pointer type is followed by an integral value enclosed in square brackets, (such as myList[0]), the result is identical to "add 0 to the pointer value and dereference it". The result of adding 0 to the address of the list and dereferencing it simply yields the list.

It is common for programmers used to C# and Java to overuse C++ new. In the posted example it is better to use Collections::List<int> myList; and the . operator instead of ->.

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Yep, that was it. When I wrote that code I didn't actually stop to think about it (yes, I'm still used to the "everything is a pointer" world of C#). I just assumed that "well, I have a class object here, all the operators/functions should work the way I implemented them, so it has to be something wrong with the operator overloading". – cantrem Feb 24 '11 at 10:02

Good that you want to learn C++ and practise writing your own collections but your logic is probably flawed.

std::vector and std::deque already allow constant-time random access. std::deque is more like a list in that it allows constant-time insertion and removal at either end and does not invalidate references or iterators due to insertions.

You also seem to be mixing your collection with its iterator into one class, so that a collection contains a current position. I am pretty certain C# collections are not implemented that way.

Finally I would imagine your MoveCursor command is O(N) which means you do not really have random-access at all.

If you want fast random access and insertion time the best you can manage is O(log N) by using a tree structure, with each node on the tree indicating the number of elements in each branch below it. Thus you can find the nth element recursing down the right path. Insertion is also O(log N) as you have to recurse up the tree modifying the counts, and you will of course have to regularly balance the tree.

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