Most vexing parse
The most vexing parse is a counterintuitive form of syntactic ambiguity resolution in the C++ programming language. In certain situations, the C++ grammar cannot distinguish between the creation of an object parameter and specification of a function's type. In those situations, the compiler is required to interpret the line as a function type specification.
Occurrence[edit]
The term "most vexing parse" was first used by Scott Meyers in his 2001 book Effective STL.[1] While unusual in C, the phenomenon was quite common in C++ until the introduction of uniform initialization in C++11.[2]
Examples[edit]
C-style casts[edit]
A simple example appears when a functional cast is intended to convert an expression for initializing a variable:
void f(double my_dbl) {
int i(int(my_dbl));
}
Line 2 above is ambiguous. One possible interpretation is to declare a variable i with initial value produced by converting my_dbl to an int. However, C allows superfluous parentheses around function parameter declarations; in this case, the declaration of i is instead a function declaration equivalent to the following:
// A function named i takes an integer and returns an integer.
int i(int my_dbl);
Unnamed temporary[edit]
A more elaborate example is:
struct Timer {};
struct TimeKeeper {
explicit TimeKeeper(Timer t);
int get_time();
};
int main() {
TimeKeeper time_keeper(Timer());
return time_keeper.get_time();
}
The line
TimeKeeper time_keeper(Timer());
is ambiguous, since it could be interpreted either as
- a variable definition for variable
time_keeperof classTimeKeeper, initialized with an anonymous instance of classTimeror - a function declaration for a function
time_keeperthat returns an object of typeTimeKeeperand has a single (unnamed) parameter, whose type is a (pointer to a) function[Note 1] taking no input and returningTimerobjects.
The C++ standard requires the second interpretation, which is inconsistent with the subsequent line 10 above. For example, Clang++ warns that the most vexing parse has been applied on line 9 and errors on the subsequent line 10:[3]
$ clang++ time_keeper.cc timekeeper.cc:9:25: warning: parentheses were disambiguated as a function declaration [-Wvexing-parse] TimeKeeper time_keeper(Timer()); ^~~~~~~~~ timekeeper.cc:9:26: note: add a pair of parentheses to declare a variable TimeKeeper time_keeper(Timer()); ^ ( ) timekeeper.cc:10:21: error: member reference base type 'TimeKeeper (Timer (*)())' is not a structure or union return time_keeper.get_time(); ~~~~~~~~~~~^~~~~~~~~
Solutions[edit]
The required interpretation of these ambiguous declarations is rarely the intended one.[4][5] Function types in C++ are usually hidden behind typedefs and typically have an explicit reference or pointer qualifier. To force the alternate interpretation, the typical technique is a different object creation or conversion syntax.
In the type conversion example, there are two alternate syntaxes available for casts: the "C-style cast"
// declares a variable of type int
int i((int)my_dbl);
or a named cast:
int i(static_cast<int>(my_dbl));
In the variable declaration example, the preferred method (since C++11) is uniform (brace) initialization.[6] This also allows limited omission of the type name entirely:
//Any of the following work:
TimeKeeper time_keeper(Timer{});
TimeKeeper time_keeper{Timer()};
TimeKeeper time_keeper{Timer{}};
TimeKeeper time_keeper( {});
TimeKeeper time_keeper{ {}};
Prior to C++11, the common techniques to force the intended interpretation were use of an extra parenthesis or copy-initialization:[5]
TimeKeeper time_keeper( /*Avoid MVP*/ (Timer()) );
TimeKeeper time_keeper = TimeKeeper(Timer());
In the latter syntax, the copy-initialization is likely to be optimized out by the compiler.[7] Since C++17, this optimization is guaranteed.[8]
Notes[edit]
- ^ According to C++ type decay rules, a function object declared as a parameter is equivalent to a pointer to a function of that type. See Function object#In C and C++.
References[edit]
- ^ Meyers, Scott (2001). Effective STL: 50 Specific Ways to Improve Your Use of the Standard Template Library. Addison-Wesley. ISBN 0-201-74962-9.
- ^ Coffin, Jerry (29 December 2012). "c++ - What is the purpose of the Most Vexing Parse?". Stack Overflow. Archived from the original on 17 January 2021. Retrieved 2021-01-17.
- ^ Lattner, Chris (5 April 2010). "Amazing Feats of Clang Error Recovery". LLVM Project Blog. The Most Vexing Parse. Archived from the original on 26 September 2020. Retrieved 2021-01-17.
- ^ DrPizza; Prototyped; wb; euzeka; Simpson, Homer J (October 2002). "C++'s "most vexing parse"". ArsTechnica OpenForum. Archived from the original on 20 May 2015. Retrieved 2021-01-17.
- ^ a b Boccara, Jonathan (2018-01-30). "The Most Vexing Parse: How to Spot It and Fix It Quickly". Fluent C++. Retrieved 2021-01-17.
- ^ Stroustrup, Bjarne (19 August 2016). "C++11 FAQ". www.stroustrup.com. Uniform initialization syntax and semantics. Retrieved 2021-01-17.
- ^ "Myths and urban legends about C++". C++ FAQ. What is copy elision? What is RVO?. Archived from the original on 17 January 2021. Retrieved 2021-01-17.
- ^ Devlieghere, Jonas (2016-11-21). "Guaranteed Copy Elision". Jonas Devlieghere. Retrieved 2021-01-17. Note, however, the caveats covered in Brand, C++ (2018-12-11). "Guaranteed Copy Elision Does Not Elide Copies". Microsoft C++ Team Blog. Retrieved 2021-01-17.
External links[edit]
- Discussion in the C++03 standard final draft (see §8.2 Ambiguity resolution [dcl.ambig.res]): https://web.archive.org/web/20141113085328/https://cs.nyu.edu/courses/fall11/CSCI-GA.2110-003/documents/c++2003std.pdf
- CppReference on direct initialization (the sort vulnerable to the most vexing parse): https://en.cppreference.com/w/cpp/language/direct_initialization
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