M.M

also make sure you have enabled as many compiler diagnostics as possible, and you aren't ignoring any messages (e.g. missing function declarations)

this makes no sense... allocation functions allocate the requested number of bytes, or return an error code. Also you should not be mixing allocators as you suggest in the last paragraph . To make this question answerable, include a stackoverflow.com/help/minimal-reproducible-example

The answer to this question depends on what is in ... So it can't really be answered as shown ; in brief the code is only correct if there is an object of void * type , or a type that is permitted to be aliased as void * such as void const *, at the location

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

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

@Alexander In the pictures it could be seen there were several diagnostic messages prior to the one you picked out to include in the question

@Alexander the error messages posted should be the ones from the exact code in the question (not from some edited version of it). The stuff you think has nothing to do with it, actually does have something to do with it.

@Alexander well, you will have to declare your things in such on order that you do not use identifiers before they have been declared.

I would suggest editing the question so that the code in the question is the exact code you were asking about (i.e. the code from the first screenshot), and include all the diagnostic messages. As explained above it's confusing to select one diagnostic and not mention the earlier ones, because of how errors cascade when the compiler tries to guess what you meant by an earlier error.

The "working code" in the screenshot is also wrong. You're being confused by the compiler seeing the early error, making something up so it can continue, and continuing to try and process the rest of the program despite the error. Which has cascading effects of bogus error messages such as the one involving the -> operator later. Unfortunately this is common behaviour of compilers for some reason. To avoid this situation, ignore any diagnostic messages other than the first one. Fix the first one and recompile. Don't run any program that produced diagnostic messages.

Ideally configure your compiler to stop compilation in case of any mistakes in the program (IDK what the setting would be called for that specific compiler but maybe check what ooptions it has)

@Alexander ListElem * would be even clearer. If anyone doesn't know what * means then now would be a good time to learn !

@StaceyGirl NULL may be defined as 0 in C, so your first comment saying that it is valid to use as a sentinel (e.g. for execl) is not correct

anyway I have to go now but I will work on my understanding of res.on.data.races/3

It's implied in "Returns: X" that the function is allowed to produce X

Hardly ... this clause does for example prevent x[1] = 'a'; from changing x[2] , and in general , from unrelated values being changed by an operation

It seems to me that implementing the specified behavior would be covered by "otherwise specified" .

Which it could achieve by writing the value at that time

My response to container.requirements.general#11 is that data() is specified as producing a null temrinator so covered by "unless otherwise specified" -- functions are allowed to do what is needed to implement the behaviour they are specified to produce

BTW if you're allowing synchronization then this whole discussion is moot as the conforming implementation of std::string could use a synchronization object for data() etc. to write the null terminator . (To be clear I don't think it is necessary but you do) . And that is still O(1) since it is a fixed cost regardless of the string size

That paragraph makes no mention of synchronization. shared_ptr has explicit thread safety guarantees in its definition

const member function that takes no arguments, let's say for simplicity

So to be clear, your interpretation of res.on.data.races/3 is: a const member function of a standard library object cannot modify any bytes of storage of the object, nor any bytes of storage that are in memory pointed to by pointers stored in the object; even including writing the same byte to a location that it already has?

OK, fair point @ member functions

Re. the combinations of requirements: it's true to some extent but I think the data race claim is outside the realm of a reasonable such chain of requirements on this point

regarding res.on.data.races/3 again, it says "non-const arguments, including this." , I take that to mean this is a non-const argument (which is true -- it's a non-const rvalue of type: pointer to const T). If your interpretation is correct (i.e. that the object cannot modify anything via this) then why would it say "including this" if there are no allowed cases via this?

Even taking your view that the null terminator is stored by the container, its value is 0 the whole time, and it is only potentially the representation of the string being changed , not its value

If you refer to container.requirements.general#11 -- I would not say that writing the null terminator changes the value of any object in the container.

The user can't but there is no restriction on the implementation

So is the data race the only problem you have with my answer?

But not that they both have a null terminator somewhere down the line. The implementation suggested in my answer does meet the requirement you just quoted (i.e. only writing the terminator when c_str(), data() or operator[](str.size()) are called)

The text you just quoted does not support the claim that &str[0] + str.size() is a dereferencable pointer . That text is from c_str()

Having said that, I don't think [res.on.data.races]/3 would apply here as it allows modification via this, which is what would be happening for writing the null terminator. The note in point 4 provides an example that this clause is talking about things like a static object.

regarding the thread-safety claim: without specifically addressing it yet -- I reject the concept that that some argument about thread-safety can impinge on the issue of null termination of &str[0] ; i.e. if the authors of the standard intended &str[0] to be null-terminated then they ought to have included direct text to that effect, instead of hoping that people infer it from overall thread safety requirements . [...]

Provide standard quotes for that last claim

I'm not saying anything about "owning". And the 5th doesn't have to be there ,as per my original answer (you are using circular logic in asserting that it has to be there in order to prove your claim that it has to be there)

@Caleth I don't agree, if a container's size() is 4 then it contains 4 elements . There can be various amounts of bookkeeping and other storage used by the container, but this clause is referring to the conceptual contents of the container, not the bookkeeping

@Caleth But it does explicitly specify that data() shall provide a null terminator. Also in your quote "object in the container" refers to the object being contained; not to any internal detail of the container

@Mgetz The implementation is not part of the program

@Caleth I'm not aware of the standard providing any guarantee about thread-safety of any std::string operation (or any other standard container unless explicitly mentioned), in general any standard library object might contain or point to storage that can be modified by a const member function . If you can point to something in the standard that talks about thread safety of std::string then go ahead

@Mgetz No it wouldn't . Iterator invalidation applies to calls the user makes to member functions of the string , not by any internal operation the implementation makes. The implementation only has to provide the guarantees that the standard places on the observable behaviour

@Caleth look, no errors . (Reiterate my point that a const member function may modify dynamically allocated storage)

@Caleth The text you quote was added in C++20

@Mgetz placing a null terminator is O(1) since the length is known. A const member function is allowed to modify mutable internal storage of an object; and any dynamically allocated storage that the object holds an internal pointer to

@chqrlie the original question decremented in_word when false; it's been edited

@samuelbrody1249 rephial.org perhaps

Don't assume that just because a project is popular it must be a model of good coding style :)

sprintf_s takes different arguments than sprintf, you could disable those rubbish warnings (sprintf is not deprecated)

sounds like you made some typo (or buff is too small)

@wellinthatcase how are you viewing the output of FormatMessage? whatever that is, output the integer (possibly converted to string) instead