It's more subtle than the other answers suggest. There is no absolute divide between data on the stack and data on the heap based on how you declare it. For example:
In the body of a function, that declares a
vector (dynamic array) of ten integers on the stack. But the storage managed by the
vector is not on the stack.
Ah, but (the other answers suggest) the lifetime of that storage is bounded by the lifetime of the
vector itself, which here is stack-based, so it makes no difference how it's implemented - we can only treat it as a stack-based object with value semantics.
Not so. Suppose the function was:
void GetSomeNumbers(std::vector<int> &result)
// fill v with numbers
So anything with a
swap function (and any complex value type should have one) can serve as a kind of rebindable reference to some heap data, under a system which guarantees a single owner of that data.
Therefore the modern C++ approach is to never store the address of heap data in naked local pointer variables. All heap allocations must be hidden inside classes.
If you do that, you can think of all variables in your program as if they were simple value types, and forget about the heap altogether (except when writing a new value-like wrapper class for some heap data, which ought to be unusual).
You merely have to retain one special bit of knowledge to help you optimise: where possible, instead of assigning one variable to another like this:
a = b;
swap them like this:
because it's much faster and it doesn't throw exceptions. The only requirement is that you don't need
b to continue to hold the same value (it's going to get
a's value instead, which would be trashed in
a = b).
The downside is that this approach forces you to return values from functions via output parameters instead of the actual return value. But they're fixing that in C++0x with rvalue references.
In the most complicated situations of all, you would take this idea to the general extreme and use a smart pointer class such as
shared_ptr which is already in tr1. (Although I'd argue that if you seem to need it, you've possibly moved outside Standard C++'s sweet spot of applicability.)