I doubt locality helps performance at all - admittedly small objects tend to be created at the same time in the same area of the heap (but this applies to C as well), over time, these small objects that remain will be compacted into a closely related area of the heap and it is supposedly this that give you an advantage over C-style allocations. However, show me a program that uses just these small objects and I'll show you a program that does sod all. Show me a program that passes all objects that are to be used on the stack and I'll show you one that screams with speed.
The de-allocation of memory is a performance benefit, short-term as they do not need to be de-allocated. However, when the garbage collector does kick in, this benefit disappears. Usually though, the collection occurs when nothing else is happening in the system (theoretically) so the cost is effectively nullified.
Compaction of the heap also helps allocation, all allocations can come from the beginning of the heap, and the memory manager doesn't have to walk the heap looking for the next free space block of the right size. However, traditional systems can gain the same amount of speed by using multiple fixed-block heaps (which mean you always allocate from a heap for the size of block you want, and you always allocate a fixed block, so walking the heap is just to find the first free block, and this can be removed using a bitmap)
So all in all, there isn't much of a benefit at all, except in benchmarks of course. In my experience the GC can and will jump in and slow you down dramatically at just the wrong time, usually when the system memory is getting filled because the user has done something like load a new page that required a lot of memory allocations.... which in turn required a collection.
It also has a tendency to use a lot of memory - 'memory is cheap' is the mantra of GC languages, so programs are written with this in mind, which means memory allocations are much more common, especially for temporaries and intermediate objects. Just look to StringBuilder classes for the evidence that this is well known. Strings may be 'solved' using this, but many other objects are still allocated with wild abandon. Any program that uses a lot of memory will find itself struggling with RAM IO - all that memory has to be brought into the CPU caches to be used, the more memory you use, the more IO your CPU MM will have to do and that can kill performance in the wrong circumstances.
In addition, when a GC occurs, you have to handle Finalised objects too, this isn't quite as bad as it used to be, but it can still halt your program while the finalisers are run.
Old Java GCs were dreadful for perf, though a lot of research has made them significantly better, they are still not perfect.
one more thing about localisation, imagine creating an array and adding a few items, then do a load of allocations, then you want to add another item to the array - with a GC system the added array element will not be localised, even after a compaction, each object in the array will be stored as an individual item on the heap. This is why I think the localisation issue is not as big a deal as it's made out to be. Now, compare that to an array that is allocated with a buffer and objects are allocated within the buffer space. That may require a re-alloc and copy to add a new item, but reading and modifying it is super fast.