What is the advantage in de-allocating memory in reverse order to variables?
Consider this example:
It's not just about deallocating memory, it's about symmetry in a broader sense.
Each time you create an object you are creating a new context to work in. You "push" into these contexts as you need them and "pop" back again later -- symmetry is necessary.
It's a very powerful way of thinking when it comes to RAII and exception-safety, or proving correctness w.r.t. preconditions and postconditions (constructors establish invariants, destructors ought to
IMHO, lack of this feature is Java's single biggest flaw. Consider objects whose constructors open file handles or mutexes or whatever -- Armen's answer brilliantly illustrates how this symmetry enforces some common-sense constraints (languages such as Java may let Object1 go out of scope before Object2 but Object2 keeps Object1 alive by reference counting) but there's a whole wealth of design issues that fall neatly into place when considered in terms of object lifetimes.
Lots of C++ gotchas explain themselves when you bear this in mind
The guarantee of destruction order of local variables is to allow you to write (for example) code like this:
Suppose that destruction order were not specified by the standard, then we'd have to worry about the possibility that this code would release the lock (allowing other threads to access the file), and only then set about flushing and closing it. Or to keep the guarantee we need, we'd have to write the code like this, instead:
This example isn't perfect - flushing a file isn't guaranteed to actually succeed, so relying on an
There are also other guarantees of destruction order in C++, for example that base class subobjects are destroyed after the derived class destructor has run, and that data members of an object are destroyed in reverse order of construction, also after the derived class destructor is run and before the base class subobjects. Each guarantee is there so that you can write code that relies in some way on the second thing still being there while the first thing is destroyed.
None of this has very much to do with the actual de-allocation of memory, it's much more about what the destructor does. Since you ask about de-allocation, though, there might be some cases where certain memory allocator implementations benefit from blocks being freed in reverse order of their allocation. It could make it a little bit easier for the allocator to reduce memory fragmentation by merging adjacent free blocks. You don't very often have to think about that, though, and anyway allocators that need to merge free blocks ought to be smart enough to do it whatever order they're allocated and freed.