IInspectable

@EmperorEto "You're obviously not going to agree with me." - Correct. I won't agree with an opinion not backed by facts. "I'm not wrong on either point" - I literally just debunked every statement made. It's hard to conclude that those statements weren't wrong. "All I can do is vote." - Now that I wholeheartedly welcome! This place would be healthier if we didn't charge for down-votes on proposed answers.

@EmperorEto "Windows Runtime is what supports the sandboxing" - Wrong again. API sets (rolled out during the Windows 7 timeframe) are the foundational technology that supports "sandboxing". In theory, API sets can be used by any application model to restrict access. The UWP is but one platform implementation that does.

@EmperorEto ""UWP" was the name for the application/UI framework" - That's incorrect. The UWP describes a platform mandating a specific application model (that never received a name, either; it got approximated by "Windows Store App" or "Microsoft Store App"). The UI framework was equally left unnamed. "There's nothing and never was anything ultimately released called Windows Presentation Platform." - I know. I'd been repeating that it remains unnamed. The Tech Community Talk I linked to went missing.

@EmperorEto "The UI framework is now called WinUI" - No, that's wrong. WinUI is an external UI library that doesn't ship with the OS. WinUI 2 can be used when targeting the UWP but it is distinctly different from the system component implementing the UI used by the UWP (it's hard to phrase since that UI framework doesn't have a name, unlike, say, "Windows Forms" or "WPF").

@EmperorEto "Additionally at the time this post was authored WinRT did have a standard name - Universal Windows Platform (UWP) - though it took many years to go from Metro to "Modern" to "UAP" and then finally UWP" - Please be more careful when reading. This answer explicitly calls out the UI Framework as not having a name. To date, this statement holds true.

@EmperorEto ""The Runtime" was always the thing cited in the documentation as preventing you from, for example, accessing files outside the user area or using Win32 APIs you weren't supposed to." - Maybe that was in the documentation. But it was never the Windows Runtime that implemented any sandboxing. It had always been the platform (the UWP as introduced in Windows 10, and its predecessor that - color me surprised - never had an official name either).

@EmperorEto "WPF and standard Win32 have nothing to do with "Windows Runtime"" - This answer doesn't claim otherwise. It specifically says that Windows Runtime types can be used from WPF and classic Win32 applications. "Windows Runtime (RT) was introduced with Windows 8 as [an] attempt to move Windows to a sandbox system." - The Windows Runtime makes no attempt whatsoever to "sandbox" access to system resources. You must be confusing the technology ("Windows Runtime") with one of its most prominent clients ("Universal Windows Platform").

@jul: The information is scattered around the MSDN. The most enlightening tidbit - to me - is from The Component Object Model: "COM [...] is not an object-oriented language but a standard. [...] The only language requirement for COM is that code is generated in a language that can create structures of pointers and, either explicitly or implicitly, call functions through pointers. Object-oriented languages [...] provide programming mechanisms that simplify the implementation of COM objects [...]."

That said, so far as I know, a hypothetical C/WinRT language projection would still be possible. I don't see much any merit in this, though: It would just mean programming against the ABI. Which is the cumbersome job that all the other language projections do for you.

@jul: COM supports only interface inheritance at the ABI level. That doesn't place restrictions on the implementation. A COM object implemented in C++ is free to derive from base classes (like the winrt::implements class template), so long as it maintains a COM-compatible v-table layout for the inherited interfaces. WinRT still uses the same COM invented in the mid-90's. C++/WinRT conveniently (to some) hides all of ABI-level mechanics, mapping the "classy" WinRT API to familiar C++ idioms.

Correct, just your average dialog-based Win32 application, with a single line of code inside wWinMain, that returns whatever DialogBoxParamW returns. To me that's still the fastest way to get a C++ application with a GUI up and running. And yes, as long as you are running on Windows 10, you get access to all functionality exposed through the Windows Runtime (with few exceptions, the require an app identity, and need to run in an app container).

That really depends on what you need. For my personal tools I often just use a classic Desktop UI, a main dialog, scripted within an .rc file, plus a lot of C++/WinRT to interface with the Windows Runtime. And a fair amount of Win32 API calls, either because there's no equivalent in the Windows Runtime, or simply because it's less of a hassle to open a file in the Windows API. You can mix all of that inside a single application, even a command line application. Using XAML with C++/WinRT is still troublesome. It's fun, when it works, but it frequently doesn't.

I don't know how widely it is really used. I believe it's replaced everything that used to be WRL and C++/CX inside Microsoft. Outside Microsoft I have not ever seen a job offer that indicated use of C++/WinRT (or even just native Windows Runtime development). MS have done an entirely poor job of explaining, what the Windows Runtime is, how language projections fit into that picture, and how UWP is not the same as the Windows Runtime. It seems like everyone thinks that the Windows Runtime is managed code, best used with C#, and requires targeting the UWP (all 3 are wrong).

Using which of those programs? The horribly formatted one, or the less horribly formatted one?

@RaymondChen I remember that you blogged about this years ago. Even more insightful than the blog entry itself were the comments that followed it (and are now lost to history). As I recall, the consensus was that GWLP_USERDATA belongs to the user of a window class, not the window class implementation. The rationale was that if a window class needed extra memory, the cbWndExtra would provide that. With that there's no justifiable reason why a window class implementation would need to use GWLP_USERDATA. Then again, maybe I misremembered.

@MichaelKenzel Seeing that you hold a language-lawyer badge you may not be prepared for the horrendous statements that come out of this user. Proceed at your own risk.

@MichaelKenzel I never claimed that this were UB in C (there isn't even UB in C, so you must be confusing this with C++). I'm literally just asking this user to provide a reference to the specific language rule they are using. Knowing this particular user well enough to know that they don't actually understand code they're writing, this would serve as a good exercise. Now if I called this off as incorrect, you'd long have seen a down-vote on this contribution.

They do not. There are situations where this is true, but it's not a general property of a union. Anyway, enough time wasted on someone that will not make the least bit of effort even just giving the impression that they'd be willing to understand. You're on your own now. Best of luck, as that seems to be the main ingredient for your faith-based code construction work.

You don't get it. You may stop right now. Literally everyone around here has told you, at one time or another, that your crude understanding of the C and C++ programming languages is ways off. Yet, you still keep fighting for your crude understanding, not coming up with anything to back your claims. Ever wondered why C++ had this awkward placement new? Once you understand what that is for, you might even have a chance of understanding what the "active memeber" of a union is all about. Once you got that, you can turn back to C.

Having the same address isn't sufficient to make this work. Though, since you are like way behind in your studies of even C, let's not waste any more time on someone that simply doesn't "get it".

Look, get yourself a few books on C, then a few books on C++. Now turn to some compiler construction literature, have a stroll around the LLVM source code, and see what transformations a compiler can do. You'd be surprised what rules it's following. They have zero overlap with your grossly simplified understanding of either language. Anyway, none of the C++ rules posted above apply (since, you know, type punning through unions in C++ simply isn't supported).

No, that rule doesn't exist in C nor C++. What you're doing isn't supported in C++.

I'm not asking how a C compiler written by someone that doesn't understand C would behave. I'm asking for the specific language rule that makes this correct. What do you not understand?

See, that's called type punning. Please explain why you believe that were correct/safe/supported. Again, I'm looking for the specific language rule(s) that apply. Everything else has been said in comments above. Time that you deliver.

You're never writing through tp, though. Explain why it is valid to read tp. I'm asking for the specific language rule(s) that apply. I mean, this is C. This cannot possibly be this difficult.

What's different? Lifetimes are a thing in C++, but not in C. I had hoped for you to explain all of this to us, since you authored the code. Code that's written by someone who doesn't actually understand the code is not generally trustworthy.

Not sure where you got the idea from that I claimed that this weren't supported. I'm just asking you to explain, why you think your code works. To this point it much sounds like you don't know why your code works, or even what language this is.

The question is tagged c. C++ language rules do not apply. Which could be of crucial importance here.

You don't seem to grasp how language specifications work. Every language construct is unspecified, unless a specific rule makes it valid. If you claim that your code is correct, there must be one or more rules that apply. I'm asking for those rules.

I've asked for clarification in my first comment. You have not produced references that would explain why type punning through a union were safe.

Type punning.

Just because you're using an anonymous union doesn't mean that you're magically not using a union. You are, and you're type punning through it. It's a mystery why you link to the C++ language specification, as the question is clearly tagged C. It's almost as though you do not understand the code you've posted.

Can you link to the specific C language rule(s) that make type-punning through a union well-defined?

"I want to know if my approach [...] is flawed. Apparently not." - Sure, if you ignore that it is flawed it may appear as not being flawed. Since there is no automatic conversion for anything COM/WinRT you don't have a solution for what is the predominant API surface.

You missed two issues: 1 You're (needlessly) introducing an additional point of failure for every API call that needs to translate input or output. 2 There are no round-trip guarantees. If you're calling SetWindowTextA followed by GetWindowTextA the input and output may be different sequences of bytes. Also, "That's a problem not restricted to UTF-8 codepage users." - True, that's an issue for all programs that rely on codepages. The wide character API is immune to that.

That's a relevant point. The entirety of the COM and WinRT API surface is strictly exposed with UTF-16 encoded string types (BSTR and HSTRING). Windows' API surface is increasingly moving towards those technologies, even replacements for old API's like GetOpenFileName are COM-based (IFileDialog, etc.). Plus, there are APIs that don't even have an ANSI version (such as CommandLineToArgvW, or TaskDialog). Use UTF-8 only when data enters or leaves the application. For everything else stick to UTF-16. If nothing else, wchar_t* is far less ambiguous than char*.

@tho UTF-16 is a variable-width encoding, like UTF-8. Storing Japanese glyphs using 16-bit code units is a solved problem since 1996.

"is there some gotcha that is waiting to trip me?" - If the documentation is accurate the obvious gotcha would be being limited to path names no longer than 260 code units. Using UTF-8 on Windows isn't entirely practical. And despite what the UTF-8 manifesto claims, the truth is that everyone is using UTF-16. UTF-8 is really only used for data interchange.

That's actually what I expected. Mutexes are global per session, not per user account. What's happening is most likely that CreateMutex returns NULL in this case: If the named mutex already exists this function requests the MUTEX_ALL_ACCESS access right, which is incompatible with the ACL on the mutex created by the (presumably) elevated process. You need to update the code that checks for existence. A simple change could be if (m_hMutex == nullptr || ::GetLastError() == ERROR_ALREADY_EXISTS ) though that may not be the most accurate.

Do you only run the program from Visual Studio or do you have a debugger attached? Does doing either one change the observed behavior? Is Visual Studio running under a different user account? Does the application when launched from Visual Studio run under a different user account? Do things change if you create the mutex into the `Global` kernel object namespace?

Don't look at the string tables. Look at the actual objects. When using Process Explorer, select the process in question and make sure the "Show Lower Pane" option is enabled. There you can see a list of all kernel objects including their names (if they are named). Mutex objects are named "Mutant".

@and Did you verify that they are the same? I included links to tools that help you see the names.

@con A mutex is perfectly fine for this. Unlike atoms. The global atom table is severely limited in size.

The mutex name is not a cryptographic secret. Anyone that has access to the executable can see it by inspecting the resource section. Anyone running the application can observe the name using tools like Process Explorer or WinObj. Though the question wasn't as much about the actual value as it was whether the values are the same in either case.

What's strOwner in either case?

That's a common pattern in the Windows API, though the documentation doesn't support passing an invalid pointer as the first argument. The SDK header (sysinfoapi.h) has the first formal parameter marked as _Out_writes_to_opt_, suggesting that the implementation is prepared to handle a null pointer argument. Not sure which of those conflicting contracts is binding.

@rem That is unfortunate. Though isn't there a way in C++ that allows for this specific use case (reserving uninitialized memory, passing it on to a C API, and then committing the valid span)?

Can't you reserve() instead, though?

You don't need to copy things around. Just allocate a std::wstring reserving enough storage, and pass its buffer into GetWindowsDirectoryW. Use this API call's return value to appropriately resize the string prior to returning. Also note that you aren't handling the case where the buffer is too small.

Executing C++ code from DllMain is guaranteed to be broken. Just remove it. Using global objects in a DLL is broken. Remove it. If you want to solve this all by yourself, be my guest.