If some function f with parameters p_1, ..., p_n of types T_1, ..., T_n respectively is called with arguments a_1, ..., a_n and its body throws an exception, finishes or returns, in what order are the arguments destroyed and why? Please provide a reference to the standard, if possible.

EDIT: I actually wanted to ask about function "parameters", but as T.C. and Columbo managed to clear my confusion, I'm leaving this question be about the arguments and asked a new separate question about the parameters. See the comments on this question for the distinction.

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    I don't know the order, but I guess the answer to the second question is "because the standard says so"... – zmbq May 2 '16 at 21:36
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    I don't think there is a pre-defined order (same as when you invoke a function with multiple params), but I'd be happy to see an answer quoting the standard. Good question, +1. – vsoftco May 2 '16 at 21:37
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    wg21.link/cwg1880. This appears underspecified. – T.C. May 2 '16 at 21:41
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    @Columbo Not really. I see people mixing them all the time. And because the lifetime of arguments isn't necessarily tied to the exit from the function - e.g. void foo(std::string); std::string s; foo(s); – T.C. May 2 '16 at 22:08
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    @Columbo I don't think I've ever encountered anyone who was that pedantic about the distinction. Most people I know use parameter and argument interchangeably main has argv and argc. not paramv and paramc. – Rob K May 3 '16 at 14:44
up vote 11 down vote accepted

The order in which the arguments to a function are evaluated is not specified by the standard. From the C++11 Standard (online draft):

5.2.2 Function call

8 [ Note: The evaluations of the postfix expression and of the argument expressions are all unsequenced relative to one another. All side effects of argument expression evaluations are sequenced before the function is entered (see 1.9). —end note ]

Hence, it is entirely up to an implementation to decide in what order to evaluate the arguments to a function. This, in turn, implies that the order of construction of the arguments is also implementation dependent.

A sensible implementation would destroy the objects in the reverse order of their construction.

  • 3
    By "platform dependent" you mean "implementation defined"? – jotik May 2 '16 at 21:52
  • @jotik, yes. "platform dependent" is the colloquial term :) – R Sahu May 2 '16 at 21:54
  • @RSahu But as an example, GCC, a compiler which runs on many platforms, may have the same implementation defined behaviour on both Linux and Windows, and the same can go for Clang. The Spec uses the term implementation defined to mean up to the implementers to decide what happens here; it has very little to do with platform per se. – cat May 2 '16 at 23:08
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    @cat, we are splitting hairs here. – R Sahu May 3 '16 at 3:13
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    I think the proper term is in fact unspecified. ISO indeed has implementation defined as a category, but that is a stronger requirement : it literally means the implementation must publicly define what choice they made. Unspecified means that the choice could vary from release to release, or even depend on compiler settings. – MSalters May 3 '16 at 9:59

I did not manage to find the answer in the standard, but I was able to test this on 3 most popular C++ compliant compilers. The answer of R Sahu pretty much explains that it is implementation defined.

§5.2.2/8: The evaluations of the postfix expression and of the arguments are all unsequenced relative to one another. All side effects of argument evaluations are sequenced before the function is entered.

Visual Studio C++ Compiler (Windows) and gcc (Debian)
Arguments are constructed in order reverse to their declaration and destroyed in reversed order (thus destroyed in order of delcaration):

2
1
-1
-2

Clang (FreeBSD)
Arguments are constructed in order of their declaration and destroyed in reversed order:

1
2
-2
-1

All compilers were instructed to treat the source code as C++11 and I used the following snippet to demonstrate the situation:

struct A
{
    A(int) { std::cout << "1" << std::endl; }
    ~A() { std::cout << "-1" << std::endl; }
};

struct B
{
    B(double) { std::cout << "2" << std::endl; }
    ~B() { std::cout << "-2" << std::endl; }
};

void f(A, B) { }

int main()
{
    f(4, 5.);
}

In §5.2.2[4] N3337 is quite explicit on what happens (online draft):

During the initialization of a parameter, an implementation may avoid the construction of extra temporaries by combining the conversions on the associated argument and/or the construction of temporaries with the initialization of the parameter (see 12.2). The lifetime of a parameter ends when the function in which it is defined returns.

So for example in

f(g(h()));

the return value from the call h() is a temporary that will be destroyed at the end of the full expression. However the compiler is allowed to avoid this temporary and directly initialize with its value the parameter of g(). In this case the return value will be destroyed once g() returns (i.e. BEFORE calling f()).

If I understood correctly what is stated in the standard however it's not permitted to have the value returned from h() to survive to the end of the full expression unless a copy is made (the parameter) and this copy is destroyed once g() returns.

The two scenarios are:

  1. h return value is used to directly initialize g parameter. This object is destroyed when g returns and before calling f.
  2. h return value is a temporary. A copy is made to initialize g parameter and it is destroyed when g returns. The original temporary is destroyed at the end of the full expression instead.

I don't know if implementations are following the rules on this.

  • The parameter objects themselves are not temporaries. – T.C. May 2 '16 at 21:43
  • T.C. they're temporaries in the context of the caller, and named objects in the context of the callee – 6502 May 2 '16 at 21:43
  • Isn't that the compiler is allowed to avoid constructing temporaries for function calls? – jotik May 2 '16 at 21:44
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    "they're temporaries in the context of the caller" {{citation needed}} – T.C. May 2 '16 at 21:46
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    @jotik: unfortunately the C++ fuzzyness about the issue is present anyway. The problem is that temporaries should be destroyed at the end of the full expression, but parameters may be destroyed at the end of the call (!). This would theoretically mean that a C++ compiler where the callee destroys the parameters would have to always make a copy from the temporary argument to the parameter so that the callee can destroy the copy but the temporary waits for the end of the function. I don't think that any compiler writer would do that to comply with rules that absurd. I think (hope). – 6502 May 3 '16 at 9:10

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