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To value initialize an object of type T, one would do something along the lines of one of the following:

T x = T();
T x((T()));

My question concerns types specified by a combination of simple type specifiers, e.g., unsigned int:

unsigned int x = unsigned int();
unsigned int x((unsigned int()));

Visual C++ 2008 and Intel C++ Compiler 11.1 accept both of these without warnings; Comeau 4.3.10.1b2 and g++ 3.4.5 (which is, admittedly, not particularly recent) do not.

According to the C++ standard (C++03 5.2.3/2, expr.type.conv):

The expression T(), where T is a simple-type-specifier (7.1.5.2) for a non-array complete object type or the (possibly cv-qualified) void type, creates an rvalue of the specified type, which is value-initialized

7.1.5.2 says, "the simple type specifiers are," and follows with a list that includes unsigned and int.

Therefore, given that in 5.2.3/2, "simple-type-specifier" is singular, and unsigned and int are two type specifiers, are the examples above that use unsigned int invalid? (and, if so, the followup is, is it incorrect for Microsoft and Intel to support said expressions?)

This question is more out of curiosity than anything else; for all of the types specified by a combination of multiple simple type specifiers, value initialization is equivalent to zero initialization. (This question was prompted by comments in response to this answer to a question about initialization).

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How dare you question me. :3 I think the expression (unsigned int) names a type, though. –  GManNickG Jan 27 '10 at 1:49
    
@GMan: (unsigned int)() fails with gcc 3 & 4 and also with VC8. typedefed versions work of course. –  Georg Fritzsche Jan 27 '10 at 1:51
    
H​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​​m. :(​​​​​​​​ –  GManNickG Jan 27 '10 at 1:55

4 Answers 4

up vote 6 down vote accepted

I posted this question to comp.lang.c++.moderated.

Daniel Krügler of the C++ standards committee agreed with the interpretation that unsigned int is a combination of simple type specifiers, and is not itself a simple type specifier.

Concerning the caption of table 7 referenced by Jerry Coffin, Krügler says:

I agree that the header of Table 7 (which is Table 9 in the most recent draft N3000) is somewhat misleading, but the preceeding text in [dcl.type.simple]/2 looks very clear to me, when it says:

Table 7 summarizes the valid combinations of simple-type-specifiers and the types they specify."

(I apologize it took me so long to post this back here from the newsgroup; it completely slipped my mind)

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In §7.1.5.2, keep reading down to table 7, which has the full list of what's allowed as a simple specifier (which does include "unsigned int").

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3  
I'd say the the table is not intended to define the notion of "simple type specifier". Moreover, the wording after the table mentions "multiple simple type specifiers". This is the wording that allows us to use unsigned int and int unsigned interchangeably, which probably means that unsigned int is in fact multiple simple type specifiers. –  AnT Jan 27 '10 at 3:12
    
@AndreyT: That was my interpretation as well. I also think the header of the table column, "Specifier(s)" implies as much. –  James McNellis Jan 27 '10 at 3:36
    
Hmm...in my copy of the standard, the title of the table is "Simple type specifiers and the types they specify." With that title, it seems like an awful stretch to believe that something in the table is not a simple type specifier. –  Jerry Coffin Jan 27 '10 at 4:22
    
I don't think that title excludes the interpretation that the column "Specifier(s)" contains combinations of simple type specifiers, especially in light of the grammar description in §7.1.5.2/1 and the list in §7.1.5/1. I've been wrong before, though. (On a totally unrelated note, is there an easy way to put the § character into answers and comments?) –  James McNellis Jan 27 '10 at 4:50
    
@James McNelis: I don't think it completely excludes the interpretation, but I do think it makes it a stretch. Entering §: under Windows, you press Alt then enter the decimal code with a leading zero (0167) using the numeric keypad. Under Linux you hold the Alt and Ctrl keys while typing in the hex value (A7). If you do it a lot, X supports an ~/.Xmodmap file, and Windows has a keyboard layout creator. For other systems, you'll probably have to do some Googling... –  Jerry Coffin Jan 27 '10 at 5:31

Hmm, sometimes you need a typedef. If it doesn't say a diagnostic is required, then it's not incorrect for them to support this. Nevertheless, for portability, you can use a typedef (uint16_t or uint64_t, although those might not be right), or quote the typename with a template:

iterator<void, unsigned long>::value_type( 5 )

How's that for unreasonably verbose?

Edit: Duh, or simply 5ul. That leaves unsigned short, unsigned char, and signed char as the only types you can't easily explicitly construct.

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I'd rather have: template <typename T> struct same_type{ typedef T type; };, little easier. –  GManNickG Jan 27 '10 at 3:03
    
I'd rather have neither ;v) . I just tried to think of something in the STL. The omission of an identity template and an identity functor always baffled me. –  Potatoswatter Jan 27 '10 at 3:53
    
You are right about the correctness issue. "A conforming implementation may have extensions...provided they do not alter the behavior of any well-formed program" (1.4/8, intro.compliance); I had forgotten exactly what the rules were concerning the language grammar, extensions, and compliance. –  James McNellis Jan 27 '10 at 3:55
3  
A std::identity is present in the latest C++0x draft (cf. n3000, 20.3.3/1). –  James McNellis Jan 27 '10 at 4:01
1  
Let's praise std::identity: stackoverflow.com/questions/75538/hidden-features-of-c/… :) It's got so many nice use cases :) –  Johannes Schaub - litb Jan 30 '10 at 1:34

7.1.5.2:

The simple-type-specifiers specify either a previously-declared user-defined type or one of the fundamental types`

This implies that unsigned int i = unsigned int() is legal, since unsigned int is a fundamental type (and thus a simple-type-specifier, see 3.9.1).

same applies for types like:

long double
long long
long long int
unsigned long
unsigned long long int
short int
...
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I think there is a logical fallacy here: your argument is that, "If T is a simple type specifier, then T is either a previously defined user defined type or T is one of the fundamental types. T is a fundamental type, therefore T is a simple type specifier" (you are affirming the consequent). –  James McNellis Jan 27 '10 at 14:28
    
@James: I dont understand what you are saying, your question stated that T t = T() is legal for simple-type-specifiers, and my quote says that fundamental types ARE simple-type specifiers, so unsigned int i = unsigned int() is legal. –  smerlin Jan 27 '10 at 19:02
1  
I apologize; I clearly hadn't had enough coffee yet when I posted that this morning. I disagree with your interpretation that if T is a fundamental type, T must also a simple type specifier. I believe that T may in fact be multiple simple type specifiers (e.g. unsigned int is a fundamental type but is designated by two simple type specifiers, unsigned and int). I think there are a lot of statements to support this, e.g. 3.9.1, note 40: "See 7.1.5.2 regarding the correspondence between types and the sequences of type-specifiers that designate them" (emphasis mine) –  James McNellis Jan 27 '10 at 20:25

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