33

std::cout is an instance of std::ostream. I can see the declaration of std::cout in a file named /usr/include/c++/7/iostream:

extern ostream cout;      /// Linked to standard output

And std::ostream is defined by typedef std::basic_ostream<char> std::ostream.

What's more, it seems that you can't create an instance of std::ostream. See this demo code snippet:

#include<iostream>

int main()
{
    std::ostream os;
    return 0;
}

Here is what the compiler complains about the code snippet above:

In file included from /opt/compiler-explorer/gcc-4.9.0/include/c++/4.9.0/iostream:39:0,
                 from <source>:1:
/opt/compiler-explorer/gcc-4.9.0/include/c++/4.9.0/ostream: In function 'int main()':
/opt/compiler-explorer/gcc-4.9.0/include/c++/4.9.0/ostream:384:7: error: 'std::basic_ostream<_CharT, _Traits>::basic_ostream() [with _CharT = char; _Traits = std::char_traits<char>]' is protected
       basic_ostream()
       ^
<source>:5:18: error: within this context
     std::ostream os;
                  ^

The question arises, since the std::basic_ostream<_CharT, _Traits>::basic_ostream() is marked protected, how std::cout is created?

This link on CppReference seems not very meaningful. It does not clearly tell me how std::cout is implemented and how std::cout is created by the constructor of std::ostream. As far as I can see, the most related information is:

The global objects std::cout and std::wcout control output to a stream buffer of implementation-defined type (derived from std::streambuf), associated with the standard C output stream stdout.

And nothing more.

I am working on Ubuntu with gcc 4.9

Thanks to @NathanPierson.

He told me that

std::basic_ostream has a constructor that takes a pointer to a std::basic_streambuf object.std::cout is initialized using a pointer to an instance of some implementation-defined derived class of std::basic_streambuf.

, which moves me closer to the answer.

18
  • 3
    You can create an std::ostream instance, but you can't default-construct it. See here for more on the constructors. The page on std::cout has more details about how it's initialized--it's an implementation-defined stream buffer that it's connected to, and the implementation also has to guarantee that it's initialized appropriately early in the program. Jun 21 at 4:59
  • 1
    @DrewMcGowen But cout actually is an instance of std::ostream other than derived from std::ostream.
    – John
    Jun 21 at 5:02
  • 2
    Yes, that's correct. std::basic_ostream has a constructor that takes a pointer to a std::basic_streambuf object. std::cout is initialized using a pointer to an instance of some implementation-defined derived class of std::basic_streambuf. If you want more details, you need to specify what implementation you're asking about. Jun 21 at 5:12
  • 8
    It sounds like you won't be satisfied until you see the actual code for a standard library implementation. So, you may want to browse the code for the GNU C++ standard library as a starting point.
    – paddy
    Jun 21 at 5:18
  • 3
    @John it's up to the implementation how to implement the behaviour specified by the standard. There is no one answer, there is just what each implementation decided to do .
    – M.M
    Jun 21 at 6:22

3 Answers 3

33

how std::cout is created?

First things first, from https://en.cppreference.com/w/cpp/io/ios_base/Init :

std::ios_base::Init

This class is used to ensure that the default C++ streams (std::cin, std::cout, etc.) are properly initialized and destructed. [...]

The header <iostream> behaves as if it defines (directly or indirectly) an instance of std::ios_base::Init with static storage duration: [...]

Meh, let's do a real code example. I will be using GCC C++ library. From https://github.com/gcc-mirror/gcc/blob/master/libstdc%2B%2B-v3/include/std/iostream#L73 , this is the important part:

 // For construction of filebuffers for cout, cin, cerr, clog et. al.
 static ios_base::Init __ioinit;

Now we jump to the constructor of ios_base::Init class, in https://github.com/gcc-mirror/gcc/blob/master/libstdc%2B%2B-v3/src/c%2B%2B98/ios_init.cc#L85 :

ios_base::Init::Init()
  {
    if (__gnu_cxx::__exchange_and_add_dispatch(&_S_refcount, 1) == 0)
      {
    // Standard streams default to synced with "C" operations.
    _S_synced_with_stdio = true;

    new (&buf_cout_sync) stdio_sync_filebuf<char>(stdout);
    new (&buf_cin_sync) stdio_sync_filebuf<char>(stdin);
    new (&buf_cerr_sync) stdio_sync_filebuf<char>(stderr);

    // The standard streams are constructed once only and never
    // destroyed.
    new (&cout) ostream(&buf_cout_sync);
    new (&cin) istream(&buf_cin_sync);
    new (&cerr) ostream(&buf_cerr_sync);
    new (&clog) ostream(&buf_cerr_sync);
    cin.tie(&cout);
    cerr.setf(ios_base::unitbuf);
    // _GLIBCXX_RESOLVE_LIB_DEFECTS
    // 455. cerr::tie() and wcerr::tie() are overspecified.
    cerr.tie(&cout);

The _S_refcount is there for when you would call ios_base::Init::Init(); manually from a constructor of a static class, it protects against double initialization.

The stdio_sync_filebuf is an internal buffer for istream/ostream and it is meant to handle cstdio FILE* operations to get/put input/output data, with implementation here https://github.com/gcc-mirror/gcc/blob/master/libstdc%2B%2B-v3/include/ext/stdio_sync_filebuf.h#L56 . It inherits from std::basic_streambuf.

So cout is constructed in-place with stdio_sync_filebuf<char> as parameter. It is the first constructor mentioned here https://en.cppreference.com/w/cpp/io/basic_ostream/basic_ostream .

Now, because the stuff is constructed in-place, you might wonder how is the memory allocated? From https://github.com/gcc-mirror/gcc/blob/master/libstdc%2B%2B-v3/src/c%2B%2B98/globals_io.cc#L50 :

  // Standard stream objects.
  // NB: Iff <iostream> is included, these definitions become wonky.
  typedef char fake_istream[sizeof(istream)]
  __attribute__ ((aligned(__alignof__(istream))));
  typedef char fake_ostream[sizeof(ostream)]
  __attribute__ ((aligned(__alignof__(ostream))));
  fake_istream cin;
  fake_ostream cout;
  fake_ostream cerr;
  fake_ostream clog;

The objects are just empty char buffers of proper size and proper alignment.

And yes, you can construct ostream yourself, with __gnu_cxx::stdio_sync_filebuf on GCC:

#include <fstream>
#include <ext/stdio_sync_filebuf.h>
int main() {
    __gnu_cxx::stdio_sync_filebuf<char> mybuf_cout_sync(stdout);
    std::ostream os(&mybuf_cout_sync);
    os << "Hello world!\n";
    return 0;
}

Or, to be portable, you would write your own class that inherits from std::streambuf and construct ostream from it yourself. There are many examples online, like for example here https://stackoverflow.com/a/51250032/9072753 .

4
  • Huh. So within globals_io.cc, std::cin/std::cout/std::cerr are nothing but char arrays aligned to match the requirements of istream/ostream. Yet the iostream header and ios_init.cc declares them as externs that are actual istream/ostream objects, and uses them as such (assuming [correctly] they haven't been initialized in the latter case, since it placement news all over that memory), and I guess the linker is okay with that because it just cares that the correct amount of aligned memory is where it expects it to be? Weird. Jun 21 at 17:18
  • 3
    @ShadowRanger The linkers, as a rule, do not even care about the size and alignment, although theoretically they could... but many compilers don't bother with properly filling the size fields in the object files' symbol tables, so the linkers have to cope with that.
    – Joker_vD
    Jun 21 at 20:06
  • 2
    @ShadowRanger LTO does complain about it, but only if you build a static version of libstdc++ with LTO, which is far from the default. gcc.gnu.org/bugzilla/show_bug.cgi?id=59472 gcc.gnu.org/bugzilla/show_bug.cgi?id=64275 Jun 22 at 17:12
  • MSVC uses similar trickery to construct its cout, cin, and cerr, as well; I'm not up-to-date on the specifics, though, last time I checked was either the 2010 or 2015 build. Jun 22 at 19:56
11

A compiler and its standard library implementation may cooperate using non-standard features which are not usable by mere programmers.

This is not necessary in this case because there is a quite standard public constructor:

explicit basic_ostream(basic_streambuf<char_type, Traits>* sb);

If you have a streambuf ready, you can create an object of type ostream, and so can the standard library.

What is that streambuf exactly is a hidden implementation detail, but on a typical implementation it is probably an object of a custom class constructed from stdout (the C-style <cstdio> file pointer).

-3

I think a part of what the current answers are missing, and what is part of your question:
the name std::cout is also ‘magical’.
This means that the standard library knows about it, and provides the OS-specific necessary connections to the terminal; using the respective (and OS-specific) system calls for output, etc.

1
  • Thank you for the explanation.Any reference?What's background piping?Could you please explain that in more details for me?
    – John
    Jun 22 at 16:06

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