Your design needs to make a choice. Either take ownership and delete it, or don't take ownership. Either way, it's up to the user to know how to use your function. They either need to know that your function will destroy the image (and maybe pass their own copy as needed), or they need to be smart enough to manage their own resources.
Typically, you don't want to steal ownership away just to delete it. So I would not delete anything. If someone is silly enough to lose the ability to delete the image they pass, that's not this functions problem. In other words, you should try to protect against Murphy, but forget about protecting against Machiavelli.
That said, raw pointer use is bad! Poor C++ code is marked by manual resource management and resource issues. You should have a wrapper around an image, that will delete the image in the destructor. That way you can never leak, even if an exception is thrown. Provide it with a
reset() method which discards it's old image resource and gets a new one.
It sounds like you want shared ownership, so you'll want a reference counted resource wrapper. The issue is then solved: if someone does an "inline" allocation, it'll be put into the shared pointer and then deleted automatically when it's done. (And even better is to have an
explicit constructor so someone has to know they'll be sharing the resource.)
This is done in a smart pointer called
shared_ptr. Boost has one, TR1 has one, and C++0x has one. Just give it a custom deleted (one that frees the image), and you never worry about resource management again.
This should be done with all resources. The concept here is Scoped-bound Resource Management (SBRM); that a resource is managed automatically by taking advantage of the lifetime rules of automatic (stack) variables. It's known alos as it's original but uglier name Resource-Acquisition Is Initialization (RAII). Do some research into this area and you'll find your code is easier and cleaner.
It cannot be done without changing the type of the parameter. You could change it to:
void Foo(myClass*& bar);
Because a non-const reference can only be bound to an lvalue:
int *i = 0;
foo(i); // well-formed
foo(&j); // ill-formed
foo(new int); // ill-formed
However, this disallows taking the address of an lvalue. You can of course do the simple:
int* pj = &j;
foo(pj); // well-formed
And it works. But I don't know why you'd want to do any of this.
The above solution would allow you to modify the argument (because it's a reference). If you wanted to enforce const within the function, you could make a utility like this:
template <typename T>
require_lvalue(T& pX) :
const T& get(void) const
operator const T&(void) const
require_lvalue& operator=(const require_lvalue&);
const T& mX;
Same result, except you have a const-reference within the function.
Note that MSVC has a bug, and accepts this:
in both cases, even though it shouldn't. (It does not accept
new int(), however.)