132

I'm trying to find a convenient way to initialise 'pod' C++ structs. Now, consider the following struct:

struct FooBar {
  int foo;
  float bar;
};
// just to make all examples work in C and C++:
typedef struct FooBar FooBar;

If I want to conveniently initialise this in C (!), I could simply write:

/* A */ FooBar fb = { .foo = 12, .bar = 3.4 }; // illegal C++, legal C

Note that I want to explicitly avoid the following notation, because it strikes me as being made to break my neck if I change anything in the struct in the future:

/* B */ FooBar fb = { 12, 3.4 }; // legal C++, legal C, bad style?

To achieve the same (or at least similar) in C++ as in the /* A */ example, I would have to implement an idiotic constructor:

FooBar::FooBar(int foo, float bar) : foo(foo), bar(bar) {}
// ->
/* C */ FooBar fb(12, 3.4);

Which is good for boiling water, but not suitable for lazy people (laziness is a good thing, right?). Also, it is pretty much as bad as the /* B */ example, as it does not explicitly state which value goes to which member.

So, my question is basically how I can achieve something similar to /* A */ or better in C++? Alternatively, I would be okay with an explanation why I should not want to do this (i.e. why my mental paradigm is bad).

EDIT

By convenient, I mean also maintainable and non-redundant.

  • 2
    I think the B example is as close as you are going to get. – Marlon May 31 '11 at 0:03
  • 2
    I don't see how example B is "bad style." It makes sense to me, since you're initializing each member in turn with their respective values. – Mike Bailey May 31 '11 at 3:04
  • 22
    Mike, it's bad style because it is not clear which value goes to which member. You have to go and look at the definition of the struct and then count members to find what each value means. – jnnnnn Jan 10 '13 at 0:56
  • 8
    Plus, if the definition of FooBar were to change in the future, the initialization could become broken. – Edward Falk Mar 12 '13 at 20:44
  • if initialization gets long and complex, don't forget about the builder pattern – sled Jan 6 '16 at 0:17

12 Answers 12

6

Designated initializes will be supported in c++2a, but you don't have to wait, because they are officialy supported in GCC in Clang.

#include <iostream>
#include <filesystem>

struct hello_world {
    const char* hello;
    const char* world;
};

int main () 
{
    hello_world hw = {
        .hello = "hello, ",
        .world = "world!"
    };

    std::cout << hw.hello << hw.world << std::endl;
    return 0;
}

Demo

38

Since style A is not allowed in C++ and you don't want style B then how about using style BX:

FooBar fb = { /*.foo=*/ 12, /*.bar=*/ 3.4 };  // :)

At least help at some extent.

  • 8
    +1: it does not really ensure correct initialization (from the compiler POV) but sure helps the reader... although the comments ought to be kept in sync. – Matthieu M. May 31 '11 at 6:42
  • 15
    Comment doesn't prevent initialization of the structure from being broken if I insert new field between foo and bar in the future. C would still initialize the fields we want, but C++ would not. And this is the point of the question - how to achieve the same result in C++. I mean, Python does this with named arguments, C - with "named" fields, and C++ should have something too, I hope. – dmitry_romanov Jul 18 '13 at 6:00
  • 2
    Comments in sync? Give me a break. Safety goes through the window. Reorder the parameters and boom. Much better with explicit FooBar::FooBar(int foo, float bar) : foo(foo), bar(bar) . Note the explicit keyword. Even breaking the standard is better in regards to safety. In Clang: -Wno-c99-extensions – Daniel O Jan 20 '15 at 13:39
  • @DanielW, It's not about what is better or what is not. this answer in accordance that the OP doesn't want Style A (not c++), B or C, which covers all the valid cases. – iammilind Feb 1 '15 at 14:23
  • @iammilind I think a hint as to why OP's mental paradigm is bad could improve the answer. I consider this dangerous as it is now. – Daerst Feb 10 '15 at 15:25
8

You could use a lambda:

const FooBar fb = [&] {
    FooBar fb;
    fb.foo = 12;
    fb.bar = 3.4;
    return fb;
}();

More information on this idiom can be found on Herb Sutter's blog.

  • Such approach initializes fields twice. Once in constructor. Second is fb.XXX = YYY. – Dmytro Ovdiienko Nov 14 '18 at 14:36
7

Your question is somewhat difficult because even the function:

static FooBar MakeFooBar(int foo, float bar);

may be called as:

FooBar fb = MakeFooBar(3.4, 5);

because of the promotion and conversions rules for built-in numeric types. (C has never been really strongly typed)

In C++, what you want is achievable, though with the help of templates and static assertions:

template <typename Integer, typename Real>
FooBar MakeFooBar(Integer foo, Real bar) {
  static_assert(std::is_same<Integer, int>::value, "foo should be of type int");
  static_assert(std::is_same<Real, float>::value, "bar should be of type float");
  return { foo, bar };
}

In C, you may name the parameters, but you'll never get further.

On the other hand, if all you want is named parameters, then you write a lot of cumbersome code:

struct FooBarMaker {
  FooBarMaker(int f): _f(f) {}
  FooBar Bar(float b) const { return FooBar(_f, b); }
  int _f;
};

static FooBarMaker Foo(int f) { return FooBarMaker(f); }

// Usage
FooBar fb = Foo(5).Bar(3.4);

And you can pepper in type promotion protection if you like.

  • 1
    "In C++, what you want is achievable": wasn't OP asking to help prevent the mixup of the order of parameters? How does the template you propose would achieve that? Just for simplicity, let's say we have 2 parameters, both of them int. – max Oct 12 '17 at 23:01
  • @max: It will prevent it only if the types differ (even if they are convertible to each other), which is the OP situation. If it cannot distinguish the types, then of course it doesn't work, but that's a whole other question. – Matthieu M. Oct 13 '17 at 15:44
  • Ah got it. Yeah, these are two different problems, and I guess the second one doesn't have a good solution in C++ at the moment (but it appears C++ 20 is adding the support for the C99-style parameter names in the aggregate initialization). – max Oct 13 '17 at 21:35
5

Extract the contants into functions that describe them (basic refactoring):

FooBar fb = { foo(), bar() };

I know that style is very close to the one you didn't want to use, but it enables easier replacement of the constant values and also explain them (thus not needing to edit comments), if they ever change that is.

Another thing you could do (since you are lazy) is to make the constructor inline, so you don't have to type as much (removing "Foobar::" and time spent switching between h and cpp file):

struct FooBar {
  FooBar(int f, float b) : foo(f), bar(b) {}
  int foo;
  float bar;
};
  • I highly recommend anyone else reading this question to choose the style in the bottom code-snippet for this answer if all you're looking to do is be able to quickly initialize structs with a set of values. – kayleeFrye_onDeck Feb 17 '18 at 1:00
5

Many compilers' C++ frontends (including GCC and clang) understand C initializer syntax. If you can, simply use that method.

  • 15
    Which is not compliant to the C++ standard! – bitmask Jan 1 '13 at 15:40
  • 4
    I know it's non-standard. But if you can use it, it's still the most sensible way to initialize a struct. – Matthias Urlichs Jan 1 '13 at 21:11
  • 2
    You can protect types of x and y making wrong constructor private: private: FooBar(float x, int y) {}; – dmitry_romanov Jul 18 '13 at 6:17
  • 4
    clang (llvm based c++ compiler) also supports this syntax. Too bad it's not part of the standard. – nimrodm Nov 5 '13 at 18:17
  • We all know that C initializers are not part of the C++ standard. But many compilers do understand it and the question didn't say which compiler is being targeted, if any. Thus please don't downvote this answer. – Matthias Urlichs Apr 30 '18 at 13:37
2

Yet another way in C++ is

struct Point
{
private:

 int x;
 int y;

public:
    Point& setX(int xIn) { x = Xin; return *this;}
    Point& setY(int yIn) { y = Yin; return *this;}

}

Point pt;
pt.setX(20).setY(20);
  • 2
    Cumbersome for functional programming (i.e. creating the object in the argument list of a function call), but really a neat idea otherwise! – bitmask May 31 '11 at 0:22
  • 76
    -1. This is obviously not initialization. – Nawaz May 31 '11 at 0:25
  • 25
    the optimizer probably reduces it, but my eyes don't. – Matthieu M. May 31 '11 at 6:41
  • 6
    Two words: argh...argh! How is this better than using public data with 'Point pt; pt.x = pt.y = 20;`? Or if you want encapsulation, how is this better than a constructor? – OldPeculier Jun 14 '12 at 17:44
  • 3
    It is better than a constructor because you have to look at the constructor declaration for the parameter order ... is it x , y or y , x but the way I have showed it is evident at call site – parapura rajkumar Jun 14 '12 at 18:42
2

Option D:

FooBar FooBarMake(int foo, float bar)

Legal C, legal C++. Easily optimizable for PODs. Of course there are no named arguments, but this is like all C++. If you want named arguments, Objective C should be better choice.

Option E:

FooBar fb;
memset(&fb, 0, sizeof(FooBar));
fb.foo = 4;
fb.bar = 15.5f;

Legal C, legal C++. Named arguments.

  • 16
    -1. This is obviously not initialization. – Nawaz May 31 '11 at 0:27
  • 12
    Instead of memset you can use FooBar fb = {}; in C++, it default-initializes all struct members. – Öö Tiib May 31 '11 at 0:29
  • @Oo: Good point. – John May 31 '11 at 0:31
  • @ÖöTiib: Unfortunately that's illegal C, though. – CB Bailey May 31 '11 at 8:21
2

I know this question is old, but there is a way to solve this until C++20 finally brings this feature from C to C++. What you can do to solve this is use preprocessor macros with static_asserts to check your initialization is valid. (I know macros are generally bad, but here I don't see another way.) See example code below:

#define INVALID_STRUCT_ERROR "Instantiation of struct failed: Type, order or number of attributes is wrong."

#define CREATE_STRUCT_1(type, identifier, m_1, p_1) \
{ p_1 };\
static_assert(offsetof(type, m_1) == 0, INVALID_STRUCT_ERROR);\

#define CREATE_STRUCT_2(type, identifier, m_1, p_1, m_2, p_2) \
{ p_1, p_2 };\
static_assert(offsetof(type, m_1) == 0, INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_2) >= sizeof(identifier.m_1), INVALID_STRUCT_ERROR);\

#define CREATE_STRUCT_3(type, identifier, m_1, p_1, m_2, p_2, m_3, p_3) \
{ p_1, p_2, p_3 };\
static_assert(offsetof(type, m_1) == 0, INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_2) >= sizeof(identifier.m_1), INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_3) >= (offsetof(type, m_2) + sizeof(identifier.m_2)), INVALID_STRUCT_ERROR);\

#define CREATE_STRUCT_4(type, identifier, m_1, p_1, m_2, p_2, m_3, p_3, m_4, p_4) \
{ p_1, p_2, p_3, p_4 };\
static_assert(offsetof(type, m_1) == 0, INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_2) >= sizeof(identifier.m_1), INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_3) >= (offsetof(type, m_2) + sizeof(identifier.m_2)), INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_4) >= (offsetof(type, m_3) + sizeof(identifier.m_3)), INVALID_STRUCT_ERROR);\

// Create more macros for structs with more attributes...

Then when you have a struct with const attributes, you can do this:

struct MyStruct
{
    const int attr1;
    const float attr2;
    const double attr3;
};

const MyStruct test = CREATE_STRUCT_3(MyStruct, test, attr1, 1, attr2, 2.f, attr3, 3.);

It's a bit inconvenient, because you need macros for every possible number of attributes and you need to repeat the type and name of your instance in the macro call. Also you cannot use the macro in a return statement, because the asserts come after the initialization.

But it does solve your problem: When you change the struct, the call will fail at compile-time.

If you use C++17, you can even make these macros more strict by forcing the same types, e.g.:

#define CREATE_STRUCT_3(type, identifier, m_1, p_1, m_2, p_2, m_3, p_3) \
{ p_1, p_2, p_3 };\
static_assert(offsetof(type, m_1) == 0, INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_2) >= sizeof(identifier.m_1), INVALID_STRUCT_ERROR);\
static_assert(offsetof(type, m_3) >= (offsetof(type, m_2) + sizeof(identifier.m_2)), INVALID_STRUCT_ERROR);\
static_assert(typeid(p_1) == typeid(identifier.m_1), INVALID_STRUCT_ERROR);\
static_assert(typeid(p_2) == typeid(identifier.m_2), INVALID_STRUCT_ERROR);\
static_assert(typeid(p_3) == typeid(identifier.m_3), INVALID_STRUCT_ERROR);\
1

The way /* B */ is fine in C++ also the C++0x is going to extend the syntax so it is useful for C++ containers too. I do not understand why you call it bad style?

If you want to indicate parameters with names then you can use boost parameter library, but it may confuse someone unfamiliar with it.

Reordering struct members is like reordering function parameters, such refactoring may cause problems if you don't do it very carefully.

  • Why is it fine? – bitmask May 31 '11 at 0:06
  • 7
    I call it bad style because I think it is zero maintainable. What if I add another member in a year? Or if I change the ordering/types of the members? Every piece of code initialising it might (very likely) break. – bitmask May 31 '11 at 0:12
  • 2
    @bitmask But as long as you do not have named arguments, you would have to update constructor calls, too and I think not many people think constructors are unmaintainable bad style. I also think named initialization is not C, but C99, of which C++ is definitely not a superset. – Christian Rau May 31 '11 at 0:18
  • 2
    If you add another member in a year to end of the struct then it will be default-initialized in already existing code. If you reorder them then you have to edit all existing code, nothing to do. – Öö Tiib May 31 '11 at 0:19
  • 1
    @bitmask: The first example would be "unmaintainable" as well then. What happens if you rename a variable in the struct instead? Sure, you could do a replace-all, but that could accidentally rename a variable that shouldn't be renamed. – Mike Bailey May 31 '11 at 3:06
0

What about this syntax?

typedef struct
{
    int a;
    short b;
}
ABCD;

ABCD abc = { abc.a = 5, abc.b = 7 };

Just tested on a Microsoft Visual C++ 2015 and on g++ 6.0.2. Working OK.
You can make a specific macro also if you want to avoid duplicating variable name.

  • clang++ 3.5.0-10 with -Weverything -std=c++1z seems to confirm that. But it doesn't look right. Do you know where the standard confirms that this is valid C++? – bitmask Nov 30 '16 at 16:34
  • I do not know, but I've used that in different compilers since long time ago and did not see any problems. Now tested on g++ 4.4.7 - works fine. – deselect Nov 30 '16 at 17:57
  • 4
    I don't think this work. Try ABCD abc = { abc.b = 7, abc.a = 5 };. – raymai97 Sep 24 '17 at 16:56
  • @deselect, it works because field is initialized with value, returned by operator=. So, actually you initialize class member twice. – Dmytro Ovdiienko Nov 14 '18 at 15:14
0

For me the laziest way to allow inline inizialization is use this macro.

#define METHOD_MEMBER(TYPE, NAME, CLASS) \
CLASS &set_ ## NAME(const TYPE &_val) { NAME = _val; return *this; } \
TYPE NAME;

struct foo {
    METHOD_MEMBER(string, attr1, foo)
    METHOD_MEMBER(int, attr2, foo)
    METHOD_MEMBER(double, attr3, foo)
};

// inline usage
foo test = foo().set_attr1("hi").set_attr2(22).set_attr3(3.14);

That macro create attribute and self reference method.

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