Your experiments are way off base. id
(solely as a CPython implementation detail) does get the memory address of the object in question, but we're talking about the Python object itself, not the data it contains. sys.getsizeof
returns a number that roughly corresponds to how much memory the object occupies, but there is no guarantee that memory is contiguous.
By sheer coincidence, this almost works on str
(though it will perform a buffer overread if the string in question has cached copies of its UTF-8 or wchar_t
form, so you're risking crashing your program), but even then your test is flawed; CPython interns string literals that look like legal variable names, so if the string in question appears as a literal anywhere else in your program (including as the name of some class or function in some module you imported), it won't actually go away when you replace it. Similar implicit caches can occur if the literal string appears in any function, anywhere (it ends up being not only interned, but stored in the constants for that function).
Update: On testing, in an actual script, the reference count for 'surely'
when you hold onto a copy of it is 3
, which drops to 2
when you replace it with 'probably'
. Turns out constants are being cached even at global scope. The only reason the interactive interpreter doesn't exhibit this behavior is that it effectively eval
s each line separately, so the constant cache is discarded when the eval
completes.
And even if all that's not a problem, most (almost all) memory managers (CPython's specialized small object heap and the general heap it's built on) don't actually zero out memory when its released, so if you do look at the same address shortly after it really was released, it'll probably have pretty similar data in it.
Lastly, your gc.collect()
call won't change anything except by coincidence (of whatever happens during gc
possibly allocating memory by side-effect). str
is not a garbage collected type, as it cannot contain references to other Python objects, so it's impossible for it to be a link in a reference cycle, and the CPython garbage collector is solely concerned with collecting cyclic garbage; CPython is reference counted, so anything that's not part of a reference cycle is cleaned up automatically and immediately when the last reference disappears.
The short answer this all leads up to is: There is no way to determine, within CPython, non-heuristically, if a particular memory address has been released to the free store and made available for reuse. CPython's memory management scheme is pure implementation detail, and exposing APIs at that level of detail would create compatibility concerns when people depended on them.
The closest you're going to get is using something like the tracemalloc
module to perform basic snapshotting and compute differences in the snapshot. That's not going to give you a window into whether a specific address is still in use though AFAICT; at best it can tell you where an address that's definitely in use was allocated.
The other approach (specific to CPython) you can use is to just check the reference counts before replacing the object; sys.getrefcount
for a given name/attribute reports 2
, then del
ing (or rebinding) that name/attribute will release it (assuming no threads that might create additional references between the test and the del
/rebind). You expect 2
, not 1
, because calling sys.getrefcount
creates a temporary reference to the object in question. If it reports a number greater than 2
, del
ing/rebinding could still lead to the object being deleted eventually when the cyclic garbage collectors runs, if the object was part of a reference cycle, but for a reference count of 2
(or 1
for something otherwise unnamed, e.g. sys.getrefcount(''.join(('f', '9'))
or the like), the behavior will be deterministic.
__del__
method might be a good place to see when objects are reclaimed?__del__
on an object that participates in a reference cycle (which can happen inadvertently, e.g. because an exception was raised in the same scope, and the exception's traceback captured a reference to the frame containing both the exception and the__del__
able object) means that it will never be cycle collected at all.