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No C++ love when it comes to the "hidden features of" line of questions? Figured I would throw it out there. What are some of the hidden features of C++?

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9  
By "hidden" do you mean things that are in the spec that you don't know yet? –  Nathan Fellman Sep 16 '08 at 18:37
1  
Do bugs count? Bug = hidden "feature", correct? –  Peter C. Nov 20 '08 at 2:43
2  
Why don't you just RTFM? –  Leo Jweda Feb 1 '10 at 11:34
5  
@Laith J: Not very many people have read the 786-page ISO C++ standard from cover to cover -- but I suppose you have, and you've retained all of it, right? –  j_random_hacker Feb 14 '10 at 19:20
2  
@Laith, @j_random: See my question "What is a programmer's joke, how do I recognize it, and what is the appropriate response" at stackoverflow.com/questions/1/you-have-been-link-rolled. –  Roger Pate Feb 26 '10 at 8:57
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64 Answers

I found this blog to be an amazing resource about the arcanes of C++ : C++ Truths.

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A dangerous secret is

Fred* f = new(ram) Fred(); http://www.parashift.com/c++-faq-lite/dtors.html#faq-11.10
f->~Fred();

My favorite secret I rarely see used:

class A
{
};

struct B
{
  A a;
  operator A&() { return a; }
};

void func(A a) { }

int main()
{
  A a, c;
  B b;
  a=c;
  func(b); //yeah baby
  a=b; //gotta love this
}
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14  
Umm, hate to say it but that's actually a not very hidden "type cast operator". Anyone who's ever looked at operator overloads probably knows about this. –  Nick Bedford Mar 26 '10 at 0:49
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Local classes are awesome :

struct MyAwesomeAbstractClass
{ ... };


template <typename T>
MyAwesomeAbstractClass*
create_awesome(T param)
{
    struct ans : MyAwesomeAbstractClass
    {
        // Make the implementation depend on T
    };

    return new ans(...);
}

quite neat, since it doesn't pollute the namespace with useless class definitions...

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Primitive types have constructors.

int i(3);

works.

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6  
That's not a constructor, that's just a form of initialization, namely direct initialization. Primitive types do not have constructors. –  GManNickG Jan 6 '11 at 23:16
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One hidden feature, even hidden to the GCC developers, is to initialize an array member using a string literal. Suppose you have a structure that needs to work with a C array, and you want to initialize the array member with a default content

struct Person {
  char name[255];
  Person():name("???") { }
};

This works, and only works with char arrays and string literal initializers. No strcpy is needed!

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One example out of many: template metaprogramming. Nobody in the standards committee intended there to be a Turing-complete sublanguage that gets executed at compile-time.

Template metaprogramming is hardly a hidden feature. It's even in the boost library. See MPL. But if "almost hidden" is good enough, then take a look at the boost libraries. It contain many goodies which are not easy accesible without the backing of a strong library.

One example is boost.lambda library, which is interesting since C++ does not have lambda functions in the current standard.

Another example is Loki, which "makes extensive use of C++ template metaprogramming and implements several commonly used tools: typelist, functor, singleton, smart pointer, object factory, visitor and multimethods." [Wikipedia]

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3  
Template metaprogramming isn't hidden anymore because it was so useful. However, it's hidden in the way that the feature is not designed into C++ but rather turned up by coincidence. –  Konrad Rudolph Sep 17 '08 at 9:30
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There is no hidden features, but the language C++ is very powerful and frequently even developers of standard couldn't imagine what C++ can be used for.

Actually from simple enough language construction you can write something very powerful. A lot of such things are available at www.boost.org as an examples (and http://www.boost.org/doc/libs/1_36_0/doc/html/lambda.html among them).

To understand the way how simple language constuction can be combined to something powerful it is good to read "C++ Templates: The Complete Guide" by David Vandevoorde, Nicolai M. Josuttis and really magic book "Modern C++ Design ... " by Andrei Alexandrescu.

And finally, it is difficult to learn C++, you should try to fill it ;)

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It seems to me that only few people know about unnamed namespaces:

namespace {
  // Classes, functions, and objects here.
}

Unnamed namespaces behave as if they was replaced by:

namespace __unique_name__ { /* empty body */ }
using namespace __unique_name__;
namespace __unique_name__ {
  // original namespace body
}

".. where all occurances of [this unique name] in a translation unit are replaced by the same identifier and this identifier differs from all other identifiers in the entire program." [C++03, 7.3.1.1/1]

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I'm not sure about hidden, but there are some interesting 'tricks' that probably aren't obvious from just reading the spec.

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Most C++ developers ignore the power of template metaprogramming. Check out Loki Libary. It implements several advanced tools like typelist, functor, singleton, smart pointer, object factory, visitor and multimethods using template metaprogramming extensively (from wikipedia). For most part you could consider these as "hidden" c++ feature.

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  • pointers to class methods
  • The "typename" keyword
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There are a lot of "undefined behavior". You can learn how to avoid them reading good books and reading the standards.

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2  
How is this a feature? There are two different ways of considering it as a feature, but I see no indication of either here. -1 for being vague. –  Roger Pate Feb 26 '10 at 8:44
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From C++ Truths.

Defining functions having identical signatures in the same scope, so this is legal:

template<class T> // (a) a base template
void f(T) {
  std::cout << "f(T)\n";
}

template<>
void f<>(int*) { // (b) an explicit specialization
  std::cout << "f(int *) specilization\n";
}

template<class T> // (c) another, overloads (a)
void f(T*) {
  std::cout << "f(T *)\n";
}

template<>
void f<>(int*) { // (d) another identical explicit specialization
  std::cout << "f(int *) another specilization\n";
}
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3  
+1 for obscurity, though you yourself are obscuring things by omitting the fact the above code needs 2 more function template declarations (1 at the start, 1 in between) to compile. –  j_random_hacker Jan 22 '09 at 9:28
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Pay attention to difference between free function pointer and member function pointer initializations:

member function:

struct S
{
 void func(){};
};
int main(){
void (S::*pmf)()=&S::func;//  & is mandatory
}

and free function:

void func(int){}
int main(){
void (*pf)(int)=func; // & is unnecessary it can be &func as well; 
}

Thanks to this redundant &, you can add stream manipulators-which are free functions- in chain without it:

cout<<hex<<56; //otherwise you would have to write cout<<&hex<<56, not neat.
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  1. map::insert(std::pair(key, value)); doesn't overwrite if key value already exists.

  2. You can instantiate a class right after its definition: (I might add that this feature has given me hundreds of compilation errors because of the missing semicolon, and I've never ever seen anyone use this on classes)

    class MyClass {public: /* code */} myClass;
    
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main() does not need a return value:

int main(){}

is the shortest valid C++ program.

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1  
@Kaz: The newline is there, click 'edit' to view the source. :) –  Roger Pate Feb 26 '10 at 7:42
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There are tons of "tricky" constructs in C++. They go from "simple" implementions of sealed/final classes using virtual inheritance. And get to pretty "complex" meta programming constructs such as Boost's MPL (tutorial). The possibilities for shooting yourself in the foot are endless, but if kept in check (i.e. seasoned programmers), provide some of the best flexibility in terms of maintainability and performance.

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If operator delete() takes size argument in addition to *void, that means it will, highly, be a base class. That size argument render possible checking the size of the types in order to destroy the correct one. Here what Stephen Dewhurst tells about this:

Notice also that we've employed a two-argument version of operator delete rather than the usual one-argument version. This two-argument version is another "usual" version of member operator delete often employed by base classes that expect derived classes to inherit their operator delete implementation. The second argument will contain the size of the object being deleted—information that is often useful in implementing custom memory management.

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Indirect Conversion Idiom:

Suppose you're designing a smart pointer class. In addition to overloading the operators * and ->, a smart pointer class usually defines a conversion operator to bool:

template <class T>
class Ptr
{
public:
 operator bool() const
 {
  return (rawptr ? true: false);
 }
//..more stuff
private:
 T * rawptr;
};

The conversion to bool enables clients to use smart pointers in expressions that require bool operands:

Ptr<int> ptr(new int);
if(ptr ) //calls operator bool()
 cout<<"int value is: "<<*ptr <<endl;
else
 cout<<"empty"<<endl;

Furthermore, the implicit conversion to bool is required in conditional declarations such as:

if (shared_ptr<X> px = dynamic_pointer_cast<X>(py))
{
 //we get here only of px isn't empty
}

Alas, this automatic conversion opens the gate to unwelcome surprises:

Ptr <int> p1;
Ptr <double> p2;

//surprise #1
cout<<"p1 + p2 = "<< p1+p2 <<endl; 
//prints 0, 1, or 2, although there isn't an overloaded operator+()

Ptr <File> pf;
Ptr <Query> pq; // Query and File are unrelated 

//surprise #2
if(pf==pq) //compares bool values, not pointers!

Solution: Use the "indirect conversion" idiom, by a conversion from pointer to data member[pMember] to bool so that there will be only 1 implicit conversion, which will prevent aforementioned unexpected behaviour: pMember->bool rather that bool->something else.

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I find recursive template instatiations pretty cool:

template<class int>
class foo;

template
class foo<0> {
    int* get<0>() { return array; }
    int* array;  
};

template<class int>
class foo<i> : public foo<i-1> {
    int* get<i>() { return array + 1; }  
};

I've used that to generate a class with 10-15 functions that return pointers into various parts of an array, since an API I used required one function pointer for each value.

I.e. programming the compiler to generate a bunch of functions, via recursion. Easy as pie. :)

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The class and struct class-keys are nearly identical. The main difference is that classes default to private access for members and bases, while structs default to public:

// this is completely valid C++:
class A;
struct A { virtual ~A() = 0; };
class B : public A { public: virtual ~B(); };

// means the exact same as:
struct A;
class A { public: virtual ~A() = 0; };
struct B : A { virtual ~B(); };

// you can't even tell the difference from other code whether 'struct'
// or 'class' was used for A and B

Unions can also have members and methods, and default to public access similarly to structs.

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Adding constraints to templates.

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Member pointers and member pointer operator ->*

#include <stdio.h>
struct A { int d; int e() { return d; } };
int main() {
    A* a = new A();
    a->d = 8;
    printf("%d %d\n", a ->* &A::d, (a ->* &A::e)() );
    return 0;
}

For methods (a ->* &A::e)() is a bit like Function.call() from javascript

var f = A.e
f.call(a)

For members it's a bit like accessing with [] operator

a['d']
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My favorite (for the time being) is the lack of sematics in a statement like A=B=C. What the value of A is basically undetermined.

Think of this:

class clC
{
public:
   clC& operator=(const clC& other)
   {
      //do some assignment stuff
      return copy(other);
   }
   virtual clC& copy(const clC& other);
}

class clB : public clC
{
public:
  clB() : m_copy()
  {
  }

  clC& copy(const clC& other)
  {
    return m_copy;
  }

private:
  class clInnerB : public clC
  {
  }
  clInnerB m_copy;
}

now A might be of a type inaccessible to any other than objects of type clB and have a value that's unrelated to C.

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You can view all the predefined macros through command-line switches with some compilers. This works with gcc and icc (Intel's C++ compiler):

$ touch empty.cpp
$ g++ -E -dM empty.cpp | sort >gxx-macros.txt
$ icc -E -dM empty.cpp | sort >icx-macros.txt
$ touch empty.c
$ gcc -E -dM empty.c | sort >gcc-macros.txt
$ icc -E -dM empty.c | sort >icc-macros.txt

For MSVC they are listed in a single place. They could be documented in a single place for the others too, but with the above commands you can clearly see what is and isn't defined and exactly what values are used, after applying all of the other command-line switches.

Compare (after sorting):

 $ diff gxx-macros.txt icx-macros.txt
 $ diff gxx-macros.txt gcc-macros.txt
 $ diff icx-macros.txt icc-macros.txt
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class Empty {};

namespace std {
  // #1 specializing from std namespace is okay under certain circumstances
  template<>
  void swap<Empty>(Empty&, Empty&) {} 
}

/* #2 The following function has no arguments. 
   There is no 'unknown argument list' as we do
   in C.
*/
void my_function() { 
  cout << "whoa! an error\n"; // #3 using can be scoped, as it is in main below
  // and this doesn't affect things outside of that scope
}

int main() {
  using namespace std; /* #4 you can use using in function scopes */
  cout << sizeof(Empty) << "\n"; /* #5 sizeof(Empty) is never 0 */
  /* #6 falling off of main without an explicit return means "return 0;" */
}
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3  
No, extending std is absolutely not OK, and the standard explicitly forbids it (with one exception: overloads of swap). –  Konrad Rudolph Feb 21 '09 at 12:40
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It's allowed to specialize templates within std, as long as the specialization depends on a user defined type. It's not restricted to swap. –  Johannes Schaub - litb Oct 15 '09 at 11:15
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Your specific example however is invalid, because your specialization doesn't match any function template signature. You would have to have two reference parameters etc :) –  Johannes Schaub - litb Oct 15 '09 at 11:16
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"It is undefined for a C++ program to add declarations or definitions to namespace std or namespaces within namespace std unless otherwise specified." (17.4.3.1/1) You can't overload std::swap, etc., but you can specialize them: "A program may add template specializations for any standard library template to namespace std. Such a specialization ... results in undefined behavior unless the declaration depends on a user-defined name of external linkage and unless the specialization meets the standard library requirements for the original template." (17.4.3.1/1) –  Roger Pate Feb 26 '10 at 7:48
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Note that std::swap, in particular, cannot be partially specialized (it is a function) and cannot be overloaded (see above standard quote), so you must do something else for templates you write. Example of how to use ADL with std::swap at stackoverflow.com/questions/2197141/…. –  Roger Pate Feb 26 '10 at 7:51
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Emulating reinterpret cast with static cast :

int var;
string *str = reinterpret_cast<string*>(&var);

the above code is equivalent to following:

int var;    
string *str = static_cast<string*>(static_cast<void*>(&var));
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4  
This isn't true. The double static cast is what people typically think reinterpret_cast does. But it doesn't. They're not equivalent. static_cast guarantees that it'll yield a pointer to the same address. reinterpret_cast just provides an implementation-defined mapping. –  jalf Sep 23 '09 at 13:00
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static_cast only guarantees the same address if you cast back to the same type that you had before converting to void*. There is some hidden mystery in the Standard about some special handling of a double static_cast like shown in this answer, but i yet have to see anyone proving the real existance of this special handling beyond "there is this, but i dunno where" wordings. –  Johannes Schaub - litb Oct 15 '09 at 11:11
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Pointer arithmetics.

It's actually a C feature, but I noticed that few people that use C/C++ are really aware it even exists. I consider this feature of the C language truly shows the genius and vision of its inventor.

To make a long story short, pointer arithmetics allows the compiler to perform a[n] as *(a+n) for any type of a. As a side note, as '+' is commutative a[n] is of course equivalent to n[a].

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2  
Duplicate........ –  Billy ONeal Nov 1 '09 at 0:33
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