124

According to cppreference.com size_t is defined in several headers, namely

<cstddef>
<cstdio>
<cstring>
<ctime>

And, since C++11, also in

<cstdlib>
<cwchar> 

First of all, I wonder why this is the case. Isn't this in contradiction to the DRY principle?

Which one of the above headers should I include to use size_t? Does it matter at all?

15
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    Open corresponding header files and find the definition.
    – i486
    Apr 13, 2016 at 9:52
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    @i486 - That's a great way to write brittle non-portable code!
    – Sean
    Apr 13, 2016 at 9:53
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    @PanagiotisKanavos C headers that are part of the C++ standard library and probably aren't duplicated in any of your alleged 'true C++' headers. What was your point, exactly? Apr 13, 2016 at 9:57
  • 15
    I always used <cstddef> for std::size_t
    – Boiethios
    Apr 13, 2016 at 9:58
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    @PanagiotisKanavos Sure, generally that's good advice, but in this case it doesn't seem relevant - as there is no C++ replacement for std::size_t, and the OP wasn't advocating using legacy C functions, just observing the quote about them sharing the typedef. I doubt anyone reading this thread would be misled into using legacy types/functions because of this, but if you want to be sure they don't, then fair enough! Apr 13, 2016 at 10:05

4 Answers 4

116

Assuming I wanted to minimize the functions and types I was importing I'd go with cstddef as it doesn't declare any functions and only declares 6 types. The others focus on particular domains (strings, time, IO) that may not matter to you.

Note that cstddef only guarantees to define std::size_t, that is, defining size_t in namespace std, although it may provide this name also in the global namespace (effectively, plain size_t).

In contrast, stddef.h (which is also a header available in C) guarantees to define size_t in the global namespace, and may also provide std::size_t.

15
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    Is there any guarantee that size_t from cstddef is the same and will always be the same as the others? Seems like there should be a common header file with common definitions like size_t...
    – SnakeDoc
    Apr 13, 2016 at 20:52
  • 1
    @SnakeDoc and as if by magic, another answer here has already observed exactly that happening, via an 'internal' header. Apr 13, 2016 at 21:00
  • 5
    @SnakeDoc Yes, and that header is cstddef.
    – user253751
    Apr 14, 2016 at 1:26
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    @SnakeDoc, who says they define their own? All the standard says is it will be defined after including those headers, it doesn't say they all have to redefine it. They could all include <cstddef>, or they could all include some internal header that just defines size_t. Apr 15, 2016 at 12:27
  • 2
    Is the csttddef in the answer a typo? Maybe cstddef is meant? Dec 30, 2017 at 12:50
52

In fact the synopsis (included in the C++ standard) of several headers specifially include size_t as well as further headers define the type size_t (based on the C standard as the <cX> headers are just ISO C <X.h> headers with noted changes where removal of size_t is not indicated).

The C++ standard however, refers to <cstddef> for the definition of std::size_t

  • in 18.2 Types,
  • in 5.3.3 Sizeof,
  • in 3.7.4.2 Deallocation functions (which refers to 18.2) and
  • in 3.7.4.1 Allocation functions (also refers to 18.2).

Therefore and because of the fact that <cstddef> only introduces types and no functions, I'd stick to this header to make std::size_t available.


Note a few things :

  1. The type of std::size_t is obtainable using decltype without including a header

    If you're planning to introduce a typedef in your code anyway (i.e. because you write a container and want to provide a size_type typedef) you can use the global sizeof, sizeof... or alignof operators to define your type without including any headers at all since theose operators return std::size_t per standard definition and you can use decltype on them:

    using size_type = decltype(alignof(char));
    
  2. std::size_t is not per se globally visible although functions with std::size_t arguments are.

    The implicitly declared global allocation and deallocation functions

    void* operator new(std::size_t);
    void* operator new[](std::size_t);
    void operator delete(void*);
    void operator delete[](void*);
    

    do NOT introduce size_t, std or std::size_t and

    referring to std or std::size_t is ill-formed unless the name has been declared by including the appropriate header.

  3. The user may not redefine std::size_t although it is possible to have multiple typedefs referring to the same type in the same namespace.

    Although, the occurrence of multiple definitions of size_t within std is perfectly valid as per 7.1.3 / 3, it is not allowed to add any declarations to namespace std as per 17.6.4.2.1 / 1:

    The behavior of a C++ program is undefined if it adds declarations or definitions to namespace std or to a namespace within namespace std unless otherwise specified.

    Adding a proper typedef for size_t to the namespace does not violate 7.1.3 but it does violate 17.6.4.2.1 and leads to undefined behaviour.

    Clarification: Try not to misinterpret 7.1.3 and do not add declarations or definitions to std (except a few template specialization cases where a typedef is not a template specialization). Extending the namespace std

9
  • 1
    You miss the fact that a duplicate typedef does not introduce a new type. It merely adds a duplicate typedef, which is perfectly valid. Apr 13, 2016 at 11:58
  • @MaximEgorushkin: I do not claim that adding a redefining typedef to std is invalid because duplicate typedefs are illegal. I state that it is illegal because you simply may not add definitions to namespace std - no matter whether they would be legal. Apr 13, 2016 at 12:00
  • What could potentially break, given all we know from all these standard quotes? Apr 13, 2016 at 12:04
  • 12
    @MaximEgorushkin: Anything. That's what undefined behaviour is about, isn't it? The point that it may work or even the point that it does not break on any arbitrary compiler does not make the behaviour of the program defined according to the standard. Or as 'fredoverflow' put it nicely here: "The C++ standard has the only vote, period." Apr 13, 2016 at 12:14
  • I would like you to use your critical thinking. What could potentially break? Apr 13, 2016 at 12:19
8

All standard library header files have the same definition; it does not matter which one you include in your own code. On my computer, I have the following declaration in _stddef.h. This file is included by every file you listed.

/*
   Define the size_t type in the std namespace if in C++ or globally if in C.
   If we're in C++, make the _SIZE_T macro expand to std::size_t
*/

#if !defined(_SIZE_T) && !defined(_SIZE_T_DEFINED)
#  define _SIZE_T_DEFINED
#if defined(_WIN64)
   typedef unsigned __int64 size_t;
#else
   typedef unsigned int size_t;
#endif
#  if defined(__cplusplus)
#    define _SIZE_T std::size_t
#  else
#    define _SIZE_T size_t
#  endif
#endif
3
  • 2
    not sure, but I think it does matter for compilation time, no? Apr 13, 2016 at 9:57
  • @tobi303 not for this specific question. Yes, you may add a larger header than necessary, but then you already addedd a C header in a C++ project. Why do you need size_t in the first place? Apr 13, 2016 at 10:00
  • It's not a good idea to use OS macro sniffing to define size_t. You can define it more portably as using size_t = decltype( sizeof( 42 ) ). But there's no need, since <stddef.h> has almost zero cost. Sep 29, 2016 at 18:05
8

You could do without a header:

using size_t = decltype(sizeof(int));
using size_t = decltype(sizeof 1); //  The shortest is my favourite.
using size_t = decltype(sizeof "anything");

This is because the C++ standard requires:

The result of sizeof and sizeof... is a constant of type std::size_t. [ Note: std::size_t is defined in the standard header <cstddef> (18.2). — end note ]

In other words, the standard requires:

static_assert(std::is_same<decltype(sizeof(int)), std::size_t>::value,
              "This never fails.");

Also note, that it is perfectly fine to make this typedef declaration in the global and in std namespace, as long as it matches all other typedef declarations of the same typedef-name (a compiler error is issued on non-matching declarations).

This is because:

  • §7.1.3.1 A typedef-name does not introduce a new type the way a class declaration (9.1) or enum declaration does.

  • §7.1.3.3 In a given non-class scope, a typedef specifier can be used to redefine the name of any type declared in that scope to refer to the type to which it already refers.


To sceptics saying that this constitutes an addition of a new type into namespace std, and such an act is explicitly prohibited by the standard, and this is UB and that is all there to it; I have to say that this attitude amounts to ignoring and denying deeper understanding of the underlying issues.

The standard bans adding new declarations and definitions into namespace std because by doing so the user may make a mess of the standard library and shoot his entire leg off. For the standard writers it was easier to let the user specialize a few specific things and ban doing anything else for good measure, rather than ban every single thing which the user should not do and risk missing something important (and that leg). They did it in the past when requiring that no standard container shall be instantiated with an incomplete type, while in fact some containers could well do (see The Standard Librarian: Containers of Incomplete Types by Matthew H. Austern):

... In the end, it all seemed too murky and too poorly understood; the standardization committee didn't think there was any choice except to say that STL containers aren't supposed to work with incomplete types. For good measure, we applied that prohibition to the rest of the standard library too.

... In retrospect, now that the technology is better understood, that decision still seems basically right. Yes, in some cases it's possible to implement some of the standard containers so that they can be instantiated with incomplete types — but it's also clear that in other cases it would be difficult or impossible. It was mostly chance that the first test we tried, using std::vector, happened to be one of the easy cases.

Given that the language rules require std::size_t to be exactly decltype(sizeof(int)), doing namespace std { using size_t = decltype(sizeof(int)); } is one of those things that do not break anything.

Prior to C++11 there was no decltype and thus no way to declare the type of sizeof result in one simple statement without getting a good deal of templates involved. size_t aliases different types on different target architectures, however, it would not be an elegant solution to add a new built-in type just for the result of sizeof, and there are no standard built-in typedefs. Hence, the most portable solution at the time was to put size_t type alias in some specific header and document that.

In C++11 there is now a way to write down that exact requirement of the standard as one simple declaration.

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    @Sean What you wrote does not make any sense. Apr 13, 2016 at 9:56
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    @PanagiotisKanavos What are your talking about? This size_t is unsigned. Apr 13, 2016 at 9:59
  • 17
    @MaximEgorushkin Half of them did not understood this code... it works perfectly. However, I do not like this way : it is better, imo, to include a header and let the standard define it.
    – Boiethios
    Apr 13, 2016 at 10:01
  • 9
    Guys, at least learn the effing language before you go downvoting perfectly correct answers. Apr 13, 2016 at 10:04
  • 11
    Tom said, "There are 6 standard library headers defining the same thing! That is insane! We need one and only one definition of size_t!" One minute later, Mary said, "OMG! There are 7 definitions of size_t across standard library headers and a project header Tom is editing! There are probably more in the 3rd party libraries!" xkcd.com/927
    – user2486888
    Apr 13, 2016 at 10:05

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