Doesn’t it just mean that any given block of memory has to be completely freed before it the heap can recycle it and return it for use to someone else?

@JeremyFriesner Maybe... but what would an non completely freed block look like? When is block half freed?

Show some code, as an Minimal, Complete, and Verifiable example, in your question

@BasileStarynkevitch What do you mean?

I wouldn't call it "an extremely odd burden"; a multithreaded allocator has a very strong chance of introducing a barrier on any sort of path that would allow for your scenario of a memory block being reused from one thread to another. After all, if you have a multithreaded allocator, it needs to protect against thread-unsafe manipulation of its bookkeeping structures anyway.

@AndreyAkhmetov Yes it's likely that stealing a block from one arena (or whatever that's called) to another might introduce a synchronization; or it might use a relaxed RMW operation to steal a ptr. Either way, that wasn't the focus of that Q. Please read again the very last sentence in the Q. Which one is it?

I don't understand this question. In particular can you explain this statement differently? "Does that really mean that the visibility of any memory operation performed by a thread that does a deallocation can be expected to be extremely rarely guaranteed by code that does a memory allocation?"

@Galik IOW, can a function in thread A doing a memory allocation except to see the memory actions performed by the thread D that last deallocated that same location, if such D exists?

Are you talking about the contents of the memory or the availability of the memory for reallocation?

@Galik I'm talking about ordinary inter thread synchronization, as if some thread D released a mutex, some other thread A took it, so there is a guarantee that all memory operations done by D before the deallocation are visible in A after the allocation, that is (informally) 1) any write by A cannot be seen (or impact on any way) any read done by D; A can destroy objects used by D; 2) a read by A can see the value last written in D to the same object (unless that object has been modified or destroyed by another thread)

@curiousguy I imagine a half-freed block would be a scenario where some of the heap-metadata for tracking that block has been updated to indicate that the block is now back in the free-list, but some other heap-metadata has not yet been updated. As you can imagine, having another thread try to allocate while the heap is in an inconsistent state like that would probably go quite badly :)

@JeremyFriesner I expect each allocation pool to be protected by a mutex then.

You can have a multithreaded allocator that uses the same arena for all threads, or a separate arena for each thread. In the first case it needs to mutex away the entire arena before each operation anyway. In the second case it cannot reuse memory blocks in different threads. Either way there is no undue burden on the allocator. A hybrid strategy is possible (even likely) but it doesn't bring anything new to the table.

@n.m. "In the second case it cannot reuse memory blocks in different threads" Then each free pool would get fragmented as it stores more and more blocks originating from another? There would be no returning back of blocks to their originator?

A thread local pool would return its free memory to the shared pool once in a while.

@n.m. Yes and how exactly that resource transfer is done is the issue here.

What is the issue exactly? Please show some code that exhibits one.

@n.m. Does that transfer of ownership guarantee memory visibility? Is that a reasonable requirement?

@curiousguy I expect that also; a mutex would be a good way to fulfill the requirement mentioned in boldface.

@JeremyFriesner Yes but how is that visibility useful in practice?

It keeps programs from crashing due to race conditions.

@JeremyFriesner How is visibility useful in that special case?

@n.m. How do you determine that? That would be an excellent answer if you can prove it, refuting the hypothesis of the Q. (I'm pretty sure that it's detectable.)

I'm not sure I understand your question fully. It looks like you want to compare a newly allocated pointer with some other pointer that was previously deallocated by some other thread. How would you get these previously deallocated pointers from other threads without some form of synchronisation?

@n.m. "you want to compare" YES

So you would have to use a relaxed operations (probably RMW) to transmit the bitwise representation of a pointer.

As written in the question: "extremely bizarre code that would memorize copies of deleted addresses in the event some other thread gets back these same addresses (all while not creating any synchronization, for example via relaxed atomic RMW operations on pointer representations)."

Im general, bitwise equality of an invalid pointer to anything else doesn't entail anything at all.

@n.m. I don't think you can say anything about ptr semantics because it's an undefined mix mash of very high level almost Java pointers (so called references) and low level, bitwise representation.

But ptr are official trivial objects that you can copy with memcpy.

Making a valid ptr to an object from its representation should be possible. That's what an ABI call does. ABI only deals with representation of objects.