91

Consider:

struct Person
{
    int height;
    int weight;
    int age;
};

int main()
{
    Person p { .age = 18 };
}

The code above is legal in C99, but not legal in C++11.

What was the standard committee's rationale for excluding support for such a handy feature?

closed as primarily opinion-based by n.m., Nic Hartley, mpromonet, Vikrant, Al Foиce ѫ Aug 17 '18 at 7:30

Many good questions generate some degree of opinion based on expert experience, but answers to this question will tend to be almost entirely based on opinions, rather than facts, references, or specific expertise. If this question can be reworded to fit the rules in the help center, please edit the question.

  • 10
    It apparently didn't make sense to the design committee to include it, or it simply didn't come up in the meetings. It's worth noting that C99 designated initializers are not in any of the C++ specification versions. Constructors seem to be the preferred initialization construct, and for good reason: they guarantee consistent object initialization, if you write them correctly. – Robert Harvey Sep 11 '13 at 2:27
  • 18
    Your reasoning is backward, a language need not have a rationale for not having a feature, it needs a rationale for having one and a strong one at that. C++ is bloated enough, as it stands. – Matthieu M. Sep 11 '13 at 7:06
  • 38
    A good reason (which cannot be solved with constructors except by writing stupefying wrappers) is that whether or not you use C++, most real APIs are C, not C++, and not few of them make you supply a structure in which you want to set one or two fields -- and not necessarily the first -- but need to have the rest zero-initialized. Win32 API OVERLAPPED is such an example. Being able to write ={.Offset=12345}; would make code much clearer (and probably less error-prone). BSD sockets are a similar example. – Damon Nov 4 '13 at 12:36
  • 11
    The code in main is not legal C99. It should read struct Person p = { .age = 18 }; – chqrlie May 5 '15 at 22:54
  • 3
    @TheodoreMurdock: I'm afraid you are mistaken, both are legal C99, but different things: struct Person p = { .age = 18 }; is a definition for p with an initializer that uses a designated initializer (C11 6.7.9), struct Person p = (struct Person) { .age = 18 }; defines p with an initializer that is a postfix expression, namely a compound literal of the same type (C11 6.5.2). – chqrlie Feb 9 '16 at 0:21
29

C++ has constructors. If it makes sense to initialize just one member then that can be expressed in the program by implementing an appropriate constructor. This is the sort of abstraction C++ promotes.

On the other hand the designated initializers feature is more about exposing and making members easy to access directly in client code. This leads to things like having a person of age 18 (years?) but with height and weight of zero.


In other words, designated initializers support a programming style where internals are exposed, and the client is given flexibility to decide how they want to use the type.

C++ is more interested in putting the flexibility on the side of the designer of a type instead, so designers can make it easy to use a type correctly and difficult to use incorrectly. Putting the designer in control of how a type can be initialized is part of this: the designer determines constructors, in-class initializers, etc.

  • 10
    Please show a reference link for what you say is the reason for C++ to not have designated initializers. I can't remember having ever seen the proposal for it. – Johannes Schaub - litb Sep 11 '13 at 19:38
  • 15
    Isn't the very reason of not providing a constructor for Person that its author wanted to provide the most possible flexibility for users to set and initialize the members? The user can also already write Person p = { 0, 0, 18 }; (and for good reasons). – Johannes Schaub - litb Sep 11 '13 at 19:48
  • 7
    Something similar has recently been accepted into the C++14 spec by open-std.org/jtc1/sc22/wg21/docs/papers/2013/n3605.html . – Johannes Schaub - litb Sep 11 '13 at 19:49
  • 4
    @JohannesSchaub-litb I'm not talking about the purely mechanical, proximate cause (i.e., it hasn't been proposed to the committee). I'm describing what I believe to be the dominating factor. — Person has a very C design so C features may make sense. However C++ probably enables a better design which also obviates the need for designated initializers. — In my view removing the restriction on in-class initializers for aggregates is much more in line with the ethos of C++ than designated initializers. – bames53 Sep 11 '13 at 20:42
  • 4
    The C++ replacement for this could be named function arguments. But as of right now, name arguments don't officially exist. See N4172 Named arguments for a proposal of this. It would make code less error prone and easier to read. – David Baird Nov 29 '15 at 15:11
58

On July 15 '17 P0329R4 was accepted into the standard: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2017/p0329r4.pdf
This brings limited support for 's Designated Initializers. This limitation is described as follows by C.1.7[diff.decl].4, given:

struct A { int x, y; };
struct B { struct A a; };

The following Designated Initializations, which are valid in C, are restricted in C++:

  • struct A a = { .y = 1, .x = 2 } is invalid in C++ because designators must appear in the declaration order of the data members
  • int arr[3] = { [1] = 5 } is invalid in C++ because array designated initialization is not supported
  • struct B b = {.a.x = 0} is invalid in C++ because designators cannot be nested
  • struct A c = {.x = 1, 2} is invalid in C++ because either all or none of the data members must be initialized by designators

For and earlier Boost actually has support for Designated Intializers and there have been numerous proposals to add support to the standard, for example: n4172 and Daryle Walker's Proposal to Add Designation to Initializers. The proposals cite implementation of 's Designated Initializers in Visual C++, gcc, and Clang claiming:

We believe the changes will be relatively straightforward to implement

But the standard committee repeatedly rejects such proposals, stating:

EWG found various problems with the proposed approach, and didn't think it's feasible to try solving the problem, as it has been tried many times and every time it has failed

Ben Voigt's comments have helped me to see the insurmountable problems with this approach; given:

struct X {
    int c;
    char a;
    float b;
};

What order would these functions be called in in : struct X foo = {.a = (char)f(), .b = g(), .c = h()}? Surprisingly, in :

The order of evaluation of the subexpressions in any initializer is indeterminately sequenced [1]

(Visual C++, gcc, and Clang seem to have an agreed upon behavior as they will all make the calls in this order:)

  1. h()
  2. f()
  3. g()

But the indeterminate nature of the standard means that if these functions had any interaction the resulting program state would also be indeterminate, and the compiler wouldn't warn you: Is there a Way to Get Warned about Misbehaving Designated Initializers?

does have stringent initializer-list requirements 11.6.4[dcl.init.list]4:

Within the initializer-list of a braced-init-list, the initializer-clauses, including any that result from pack expansions (17.5.3), are evaluated in the order in which they appear. That is, every value computation and side effect associated with a given initializer-clause is sequenced before every value computation and side effect associated with any initializer-clause that follows it in the comma-separated list of the initializer-list.

So support would have required this to be executed in the order:

  1. f()
  2. g()
  3. h()

Breaking compatibility with previous implementations.
As discussed above, this issue has been circumvented by the limitations on Designated Initializers accepted into . They provide a standardized behavior, guaranteeing the execution order of Designated Initializers.

  • 3
    Sure, in this code: struct X { int c; char a; float b; }; X x = { .a = f(), .b = g(), .c = h() }; the call to h() is performed before either f() or g(). If the definition of struct X is not nearby, this is going to be very surprising. Remember that initializer expressions don't have to be side-effect free. – Ben Voigt Mar 30 '15 at 3:43
  • 2
    Of course, this is nothing new, ctor member initialization already has this issue, but it's in the definition of a class member, so tight coupling is no surprise. And designated initializers can't reference the other members the way the ctor member-initializers can. – Ben Voigt Mar 30 '15 at 3:46
  • 2
    @MattMcNabb: No, it's not more extreme. But one expects the developer implementing the class constructor to know the member declaration order. Whereas the consumer of the class might be a different programmer entirely. Since the whole point is to allow initialization without having to look up the order of members, this seems like a fatal flaw in the proposal. Since designated initializers can't reference the object being constructed, first impression is that initialization expressions could be evaluated first, in designation order, then member initialization in declaration order. But... – Ben Voigt Mar 30 '15 at 3:53
  • 2
    @JonathanMee: Well, the other question answered that... C99 aggregate initializers are unordered, so there's no expectation for designated initializers to be ordered. C++ braced-init-lists ARE ordered, and the proposal for designated initializers uses a potentially-surprising order (you can't be consistent both with lexical order, used for all braced-init lists, and member order, used for ctor-initializer-lists) – Ben Voigt Jan 6 '16 at 18:33
  • 2
    Jonathan: "c++ support would have required this to be executed in the order [...] Breaking compatibility with previous c99 implementations." I don't get this one, sorry. 1. If the order is indeterminate in C99, then obviously any actual order should be fine, including any arbitrary C++ choice. b) Not supporting the des. initializers at all kinda already breaks C99 compatibility even more... – Sz. Feb 5 '18 at 20:37
22

Designated initializer are currently included in C++20 body of work: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2017/p0329r4.pdf so we might finally see them!

  • 2
    But do note that they are restricted: In C++, designated initialization support is restricted compared to the corresponding functionality in C. In C++, designators for non-static data members must be specified in declaration order, designators for array elements and nested designators are not supported, and designated and non-designated initializers cannot be mixed in the same initializer list. This means that in particular, you still won't be able to easily make a an enum-keyed lookup table. – Ruslan Aug 29 '17 at 10:43
  • @Ruslan: I wonder why C++ restricted them so much? I understand that there could be confusion about whether the order in which items's values are evaluated and/or written to the struct matches the order in which items are specified in the initalization list, or the order in which members appear in the struct, but the solution to that would simply be to say that initialization expressions are executed in arbitrary sequence, and the lifetime of the object does not begin until initialization is complete (the & operator would return the address that the object will have during its lifetime). – supercat Aug 16 '18 at 20:51
9

A bit of hackery, so just sharing for fun.

#define with(T, ...)\
    ([&]{ T ${}; __VA_ARGS__; return $; }())

And use it like:

MyFunction(with(Params,
    $.Name = "Foo Bar",
    $.Age  = 18
));

which expands to:

MyFunction(([&] {
 Params ${};
 $.Name = "Foo Bar", $.Age = 18;
 return $;
}()));
  • Neat, creates a lambda with a variable named $ of type T, and you assign its members directly before returning it. Nifty. I wonder if there are any performance concerns with it. – TankorSmash Jun 5 '18 at 18:34
  • In an optimized build you see no traces of the lambda nor its invocation. It's all inlined. – keebus Jun 20 '18 at 13:16
5

Two Core C99 Features that C++11 Lacks mentions “Designated Initializers and C++”.

I think the ‘designated initializer’ related with potential optimization. Here I use “gcc/g++” 5.1 as an example.

#include <stdio.h>
#include <stdlib.h>
#include <assert.h>    
struct point {
    int x;
    int y;
};
const struct point a_point = {.x = 0, .y = 0};
int foo() {
    if(a_point.x == 0){
        printf("x == 0");
        return 0;
    }else{
        printf("x == 1");
        return 1;
    }
}
int main(int argc, char *argv[])
{
    return foo();
}

We knew at compilation time, a_point.x is zero, so we could expected that foo is optimized into a single printf.

$ gcc -O3 a.c
$ gdb a.out
(gdb) disassemble foo
Dump of assembler code for function foo:
   0x00000000004004f0 <+0>: sub    $0x8,%rsp
   0x00000000004004f4 <+4>: mov    $0x4005bc,%edi
   0x00000000004004f9 <+9>: xor    %eax,%eax
   0x00000000004004fb <+11>:    callq  0x4003a0 <printf@plt>
   0x0000000000400500 <+16>:    xor    %eax,%eax
   0x0000000000400502 <+18>:    add    $0x8,%rsp
   0x0000000000400506 <+22>:    retq   
End of assembler dump.
(gdb) x /s 0x4005bc
0x4005bc:   "x == 0"

foo is optimized to print x == 0 only.

For C++ version,

#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
struct point {
    point(int _x,int _y):x(_x),y(_y){}
    int x;
    int y;
};
const struct point a_point(0,0);
int foo() {
    if(a_point.x == 0){
        printf("x == 0");
        return 0;
    }else{
        printf("x == 1");
        return 1;
    }
}
int main(int argc, char *argv[])
{
    return foo();
}

And this is output of the optimized assemble code.

g++ -O3 a.cc
$ gdb a.out
(gdb) disassemble foo
Dump of assembler code for function _Z3foov:
0x00000000004005c0 <+0>:    push   %rbx
0x00000000004005c1 <+1>:    mov    0x200489(%rip),%ebx        # 0x600a50 <_ZL7a_point>
0x00000000004005c7 <+7>:    test   %ebx,%ebx
0x00000000004005c9 <+9>:    je     0x4005e0 <_Z3foov+32>
0x00000000004005cb <+11>:   mov    $0x1,%ebx
0x00000000004005d0 <+16>:   mov    $0x4006a3,%edi
0x00000000004005d5 <+21>:   xor    %eax,%eax
0x00000000004005d7 <+23>:   callq  0x400460 <printf@plt>
0x00000000004005dc <+28>:   mov    %ebx,%eax
0x00000000004005de <+30>:   pop    %rbx
0x00000000004005df <+31>:   retq   
0x00000000004005e0 <+32>:   mov    $0x40069c,%edi
0x00000000004005e5 <+37>:   xor    %eax,%eax
0x00000000004005e7 <+39>:   callq  0x400460 <printf@plt>
0x00000000004005ec <+44>:   mov    %ebx,%eax
0x00000000004005ee <+46>:   pop    %rbx
0x00000000004005ef <+47>:   retq   

We can see that a_point is not really a compile time constant value.

  • 4
    Now please try constexpr point(int _x,int _y):x(_x),y(_y){}. clang++'s optimizer seems to eliminate the comparison in your code as well. So, this is just a QoI issue. – dyp May 25 '15 at 11:13
  • I would also expect the entire a_point object to be optimized away if it had internal linkage. i.e. put it in the anonymous namespace and see what happens. goo.gl/wNL0HC – Arvid Jul 10 '15 at 0:51
  • @dyp: Even just defining a constructor is possible only if the type is under your control. You cannot do that, for example, for struct addrinfo or struct sockaddr_in, so you're left with assignments separate from declarations. – musiphil Jan 24 '17 at 19:27
  • 2
    @musiphil At least in C++14, those C-style structs can be properly set up in a constexpr function as local variables by using assignment, and then returned from that function. Additionally, my point was not to show an alternative implementation of the constructor in C++ which allows the optimization, but showcase that it is possible for the compiler to perform this optimization if the form of initialization is different. If the compiler is "good enough" (i.e. supports this form of optimization), then it should be irrelevant whether you use a ctor or designated initializers, or something else. – dyp Jan 25 '17 at 8:38

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