Do note alignment requirements.

The C++ Rules.

@JoshuaGreen: Think about: what's the difference between void * and void * *? Does a void pointer to a void pointer make sense?

As you didn't had original object, only storage for it, it's inplicit object creation.

@user16217248, I did note alignment requirements, as pointed out in my question. It seems that every answer along this topic states that you can't do this because of alignment issues. I'm carefully maintaining alignment, so I couldn't easily reject this on those grounds.

@TedLyngmo, entirely possible that this one of those areas in which the languages strongly disagree, not that I could find clear guidance for either one. My particular codebase is C, but I was curious about a general response, not expecting significant disagreement.

@ThomasMatthews, I have a pointer into a char array. I'd like to treat that segment of raw bytes as storing a void *.

@Swift-FridayPie, that's plausible, though of course the return value of malloc is always cast to implicitly create an object.

I initially misread the code, so I deleted my answer. The question will have completely different answers in C and C++ because they have quite different object models and the answer depends on these details, even if the result in the end may be the same.

I'm happy to focus on C here.

In particular in C++ it is always UB due to aliasing violation without a call to std::launder intervening the cast and access, and it is also UB if there wasn't implicit/explicit object creation of a void* object nested within the array when/after the array's lifetime began (which depends on the rest of the surrounding code.)

@user17732522 launder doesn't "fix" aliasing violations, just lifetime issues for objects of the same type

@JoshuaGreen suggest editing the tags to remove [c++]

@M.M alignas(void*) unsigned char x[sizeof(void*)]; new(x) void*; *(void**)&x[0] = 0; is an aliasing violation because &x[0] points to the char object, not the void* object, but alignas(void*) unsigned char x[sizeof(void*)]; new(x) void*; *std::launder((void**)&x[0]) = 0; has defined behavior because std::launder((void**)&x[0]) points to the explicitly-created void* object. std::launder doesn't create any objects and doesn't affect lifetimes. It doesn't fix the aliasing issue by itself, but is still required, in addition to explicit/implicit object creation.

Why are you using void pointers in C++?

@Ed-Heal, sorry for any confusion. The codebase is in C, though I'm interested in the answer for both languages. I didn't create the codebase, but I'm trying to clean it up. It's an arena allocator, and it tracks available blocks in a linked list. Its clever (to me, as I had never seen it before) trick is to store the next pointers inside the blocks.

@JoshuaGreen - Why are you using void pointers? Surely losing type safety is not a good idea. BTW That includes C and also C++

@Ed-Heal, this is an allocator written in C. It has to return generic pointers that can be then cast to any required type.

@JoshuaGreen - Please post the code for the allocator. Might be helpful

@Ed-Heal, why? Whether or not this allocator is a good idea (and it may have been decades ago when it was first written), the question of whether or not the above lines are legal should have a well-defined answer independent of what they're being used for.

Since the question is now (wrongly, imo) closed, here is my answer. Aliasing violations are so common in system level code like this that the compilers can be instructed to not be anal about it, with -fno-strict-aliasing. For context see Linus' famous rant. One way to become conformant though may be through a struct with a "flexible array member" in the end. The first member(s) are your known control data (next block pointer etc.), the array holds the actual memory block the user requested.

@M.M The whole point is that the memory there is untyped, part of a uniform memory arena. This code is what attempts to imbue meaning (like the first day of creation tells earth from heaven where before was only tohubohu).

@M.M, sorry for eliding some of the info. Please assume that bufPtr points into some large char array and ptr1 is initially set to some valid object address (cast to void *, of course).

@Peter-ReinstateMonica, the codebase makes liberal use of flexible array members elsewhere. That's not what's going on here; instead we're trying to embed pointers inside a large char array, each one inside an available chunk and pointing to the next free chunk.