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we are currently digging through some really old C++/CLI-Code (Old Syntax .NET Beta) and were a bit surprised to see something like this:

System::String ^source("Test-String");
printf("%s", source);

The program correctly outputs

Test-String

We are wondering, why is it possible to pass the managed string source to printf - and more importantly: Why does it work? I don't expect it to be some convenience-feature by the compiler because the following doesn't work:

System::String ^source("Test-String");
char pDest[256];
strcpy(pDest, source);

This produces a (somehow expected) compiling error saying that System::String^ can't be converted to const char*. So my only real explaination is that passing a managed reference to a va_list surpasses all compiler-checks and tricks the native code into using a pointer into the managed heap. Since System::String is represented similar to a char-Array in memory, printf may work. Or the compiler converts to a pin_ptr and passes that to printf.

I don't expect it to automatically marshal the String^ to char*, because that would result in a bad memory leak without any reference to the actual memory address.

We know that this isn't a good solution and the various marshalling methods introduced by the later Visual Studio-Versions provide a way better approach but it would be very interesting to understand what is actually happening here.

Thanks!

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up vote 4 down vote accepted

I believe it is because the compiler is turning it into this IL:

call vararg int32 modopt([mscorlib]System.Runtime.CompilerServices.CallConvCdecl) printf(int8 modopt([mscorlib]System.Runtime.CompilerServices.IsSignUnspecifiedByte) modopt([mscorlib]System.Runtime.CompilerServices.IsConst)*, ..., string)

Which ends up as a pinvoke call to printf, so the runtime is being a little sneaky by marshalling it for you. You are still in a managed runtime, and the runtime will provide marhsalling as a service when it's needed.


Some notes:

It seems that clr!GenericPInvokeCalliHelper is doing this lifting on the x86 .NET 4 Workstation CLR.

the following doesn't work

That's because that is straight C++. It has no chance to go through marshalling because it isn't needed.

share|improve this answer
    
So perhaps the question is, why is the compiler turning it into that IL? Since when is printf a managed function? Why is it P/Invoking it? Why isn't it calling it like any other native C++ function? – Cody Gray Aug 6 '12 at 23:19
    
@CodyGray My suspicion is it's PInvoking it because the compiler sees something needs to go through the marshaller, first. I'll verify and write something more comprehensive in a bit. – vcsjones Aug 6 '12 at 23:24
    
Thanks for the answers so far! To me the only real difference between strcpy and sprintf concerning managed strings is the fact that sprintf takes a variable arg-list and strcpy does not. And maybe that's the reason for the IL-code. – Excelcius Aug 7 '12 at 7:40
    
Thanks again for the explaination! I'll stick to this as the answer. I'm pretty sure that it is turned into IL because of the varargs though, not because the compiler notices the need for marshalling - otherwise the strcpy would work as well. – Excelcius Aug 9 '12 at 11:07

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