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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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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
Do bugs count? Bug = hidden "feature", correct? –  Peter C. Nov 20 '08 at 2:43
Why don't you just RTFM? –  Leo Jweda Feb 1 '10 at 11:34
@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
@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

64 Answers 64

Pointer arithmetics.

C++ programmers prefer to avoid pointers because of the bugs that can be introduced.

The coolest C++ I've ever seen though? Analog literals.

+1 for the analog literals -- that's insane! –  Martin B Sep 23 '09 at 12:55
I second Trevor Harrison, that IS messed up. New respect for C++! –  blwy10 Oct 18 '09 at 6:22
+1 for complete insanity –  KitsuneYMG Oct 25 '09 at 2:32
Wow. That's crazy –  Alexandre Jasmin Dec 19 '09 at 2:21
We avoid pointers because of bugs? Pointers are basically everything that dynamic C++ coding is about! –  Nick Bedford Mar 26 '10 at 0:36

main() does not need a return value:

int main(){}

is the shortest valid C++ program.

@Kaz: The newline is there, click 'edit' to view the source. :) –  Roger Pate Feb 26 '10 at 7:42

Hidden features:

  1. Pure virtual functions can have implementation. Common example, pure virtual destructor.
  2. If a function throws an exception not listed in its exception specifications, but the function has std::bad_exception in its exception specification, the exception is converted into std::bad_exception and thrown automatically. That way you will at least know that a bad_exception was thrown. Read more here.

  3. function try blocks

  4. The template keyword in disambiguating typedefs in a class template. If the name of a member template specialization appears after a ., ->, or :: operator, and that name has explicitly qualified template parameters, prefix the member template name with the keyword template. Read more here.

  5. function parameter defaults can be changed at runtime. Read more here.

  6. A[i] works as good as i[A]

  7. Temporary instances of a class can be modified! A non-const member function can be invoked on a temporary object. For example:

    struct Bar {
      void modify() {}
    int main (void) {
      Bar().modify();   /* non-const function invoked on a temporary. */

    Read more here.

  8. If two different types are present before and after the : in the ternary (?:) operator expression, then the resulting type of the expression is the one that is the most general of the two. For example:

    void foo (int) {}
    void foo (double) {}
    struct X {
      X (double d = 0.0) {}
    void foo (X) {} 
    int main(void) {
      int i = 1;
      foo(i ? 0 : 0.0); // calls foo(double)
      X x;
      foo(i ? 0.0 : x);  // calls foo(X)
Regarding your first point: There's one particular case where you have to implement a pure virtual function: pure virtual destructors. –  Frerich Raabe Oct 30 '09 at 14:56

Preventing comma operator from calling operator overloads

Sometimes you make valid use of the comma operator, but you want to ensure that no user defined comma operator gets into the way, because for instance you rely on sequence points between the left and right side or want to make sure nothing interferes with the desired action. This is where void() comes into game:

for(T i, j; can_continue(i, j); ++i, void(), ++j)
  do_code(i, j);

Ignore the place holders i put for the condition and code. What's important is the void(), which makes the compiler force to use the builtin comma operator. This can be useful when implementing traits classes, sometimes, too.

@GMan ohh great \o/ –  Johannes Schaub - litb Feb 4 '11 at 5:24
  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;

The dominance rule is useful, but little known. It says that even if in a non-unique path through a base-class lattice, name-lookup for a partially hidden member is unique if the member belongs to a virtual base-class:

struct A { void f() { } };

struct B : virtual A { void f() { cout << "B!"; } };
struct C : virtual A { };

// name-lookup sees B::f and A::f, but B::f dominates over A::f !
struct D : B, C { void g() { f(); } };

I've used this to implement alignment-support that automatically figures out the strictest alignment by means of the dominance rule.

This does not only apply to virtual functions, but also to typedef names, static/non-virtual members and anything else. I've seen it used to implement overwritable traits in meta-programs.

Neat. Any particular reason you included struct C in your example...? Cheers. –  Tony D May 11 '11 at 4:29

Lifetime of temporaries bound to const references is one that few people know about. Or at least it's my favorite piece of C++ knowledge that most people don't know about.

const MyClass& x = MyClass(); // temporary exists as long as x is in scope
It got Herb Sutter to get Guru of the Week out one last time. –  David Thornley Jan 7 '09 at 21:11
Can you elaborate? As is you're just teasing ;) –  Joseph Garvin Jun 21 '09 at 21:55
ScopeGuard (ddj.com/cpp/184403758) is a great example that leverages this feature. –  MSN Jun 22 '09 at 16:48
I am with Joseph Garvin. Please enlighten us. –  Peter Mortensen Jul 6 '09 at 21:04

Another hidden feature that doesn't work in C is the functionality of the unary + operator. You can use it to promote and decay all sorts of things

Converting an Enumeration to an integer


And your enumerator value that previously had its enumeration type now has the perfect integer type that can fit its value. Manually, you would hardly know that type! This is needed for example when you want to implement an overloaded operator for your enumeration.

Get the value out of a variable

You have to use a class that uses an in-class static initializer without an out of class definition, but sometimes it fails to link? The operator may help to create a temporary without making assumptins or dependencies on its type

struct Foo {
  static int const value = 42;

// This does something interesting...
template<typename T>
void f(T const&);

int main() {
  // fails to link - tries to get the address of "Foo::value"!

  // works - pass a temporary value

Decay an array to a pointer

Do you want to pass two pointers to a function, but it just won't work? The operator may help

// This does something interesting...
template<typename T>
void f(T const& a, T const& b);

int main() {
  int a[2];
  int b[3];
  f(a, b); // won't work! different values for "T"!
  f(+a, +b); // works! T is "int*" both time
Didn't know this one. Very nice! –  jweyrich Jul 5 '10 at 23:09
All I can say is: Whoa. –  Martín Fixman Jul 5 '10 at 23:50
Very cool indeed. I almost didn't believe you, since this is the first time I've heard of a unary + operator... But it checks out :-) –  Tomer Vromen Jul 6 '10 at 20:49

Another hidden feature is that you can call class objects that can be converted to function pointers or references. Overload resolution is done on the result of them, and arguments are perfectly forwarded.

template<typename Func1, typename Func2>
class callable {
  Func1 *m_f1;
  Func2 *m_f2;

  callable(Func1 *f1, Func2 *f2):m_f1(f1), m_f2(f2) { }
  operator Func1*() { return m_f1; }
  operator Func2*() { return m_f2; }

void foo(int i) { std::cout << "foo: " << i << std::endl; }
void bar(long il) { std::cout << "bar: " << il << std::endl; }

int main() {
  callable<void(int), void(long)> c(foo, bar);
  c(42); // calls foo
  c(42L); // calls bar

These are called "surrogate call functions".

When you say overload resolution is done on the result of them, do you mean it actually converts it to both Functors and then does overload resolution? I tried printing something in operator Func1* (), and operator Func2* (), but it seems to pick the correct one when it figures out which conversion operator to invoke. –  navigator Jul 8 '10 at 11:32
@navigator, yep it conceptually converts to both and then picks the best. It does not need to actually call them, because it knows from the result-type what they will yield already. The actual call is done when it turns out what was finally picked. –  Johannes Schaub - litb Jul 8 '10 at 18:51

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!


Primitive types have constructors.

int i(3);


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

Local classes are awesome :

struct MyAwesomeAbstractClass
{ ... };

template <typename T>
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...


You can return a variable reference as part of a function. It has some uses, mostly for producing horrible code:

int s ;
vector <int> a ;
vector <int> b ;

int &G(int h)
    if ( h < a.size() ) return a[h] ;
    if ( h - a.size() < b.size() ) return b[ h - a.size() ] ;
    return s ;

int main()
    a = vector <int> (100) ;
    b = vector <int> (100) ;

    G( 20) = 40 ; //a[20] becomes 40
    G(120) = 40 ; //b[20] becomes 40
    G(424) = 40 ; //s becomes 40
I wouldn't call that hidden - common examples are the stream-operators, operator* for iterators, prefix ++, std::vector<T>::front(), compound-assignments, ... –  Georg Fritzsche Jul 5 '10 at 0:43

I agree with most posts there: C++ is a multi-paradigm language, so the "hidden" features you'll find (other than "undefined behaviours" that you should avoid at all cost) are clever uses of facilities.

Most of those facilities are not build-in features of the language, but library-based ones.

The most important is the RAII, often ignored for years by C++ developers coming from the C world. Operator overloading is often a misunderstood feature that enable both array-like behaviour (subscript operator), pointer like operations (smart pointers) and build-in-like operations (multiplying matrices.

The use of exception is often difficult, but with some work, can produce really robust code through exception safety specifications (including code that won't fail, or that will have a commit-like features that is that will succeed, or revert back to its original state).

The most famous of "hidden" feature of C++ is template metaprogramming, as it enables you to have your program partially (or totally) executed at compile-time instead of runtime. This is difficult, though, and you must have a solid grasp on templates before trying it.

Other make uses of the multiple paradigm to produce "ways of programming" outside of C++'s ancestor, that is, C.

By using functors, you can simulate functions, with the additional type-safety and being stateful. Using the command pattern, you can delay code execution. Most other design patterns can be easily and efficiently implemented in C++ to produce alternative coding styles not supposed to be inside the list of "official C++ paradigms".

By using templates, you can produce code that will work on most types, including not the one you thought at first. You can increase type safety,too (like an automated typesafe malloc/realloc/free). C++ object features are really powerful (and thus, dangerous if used carelessly), but even the dynamic polymorphism have its static version in C++: the CRTP.

I have found that most "Effective C++"-type books from Scott Meyers or "Exceptional C++"-type books from Herb Sutter to be both easy to read, and quite treasures of info on known and less known features of C++.

Among my preferred is one that should make the hair of any Java programmer rise from horror: In C++, the most object-oriented way to add a feature to an object is through a non-member non-friend function, instead of a member-function (i.e. class method), because:

  • In C++, a class' interface is both its member-functions and the non-member functions in the same namespace

  • non-friend non-member functions have no privileged access to the class internal. As such, using a member function over a non-member non-friend one will weaken the class' encapsulation.

This never fails to surprise even experienced developers.

(Source: Among others, Herb Sutter's online Guru of the Week #84: http://www.gotw.ca/gotw/084.htm )

+1 for mentioning the free functions. :-) –  Konrad Rudolph Sep 17 '08 at 9:35
@wilhelmtell: No no no... :-p ... I DO mean "its member-functions and NON-FRIEND non-member functions".... Koenig's Lookup will make sure these functions will be considered sooner than other "outside" functions in its search for symbols –  paercebal Oct 30 '08 at 21:45
Great post, and +1 especially for the last part, which far too few people realize. I'd probably add the Boost library as a "hidden feature" as well. I pretty much consider it the standard library that C++ should have had. ;) –  jalf Nov 19 '08 at 17:04

Not actually a hidden feature, but pure awesomeness:

#define private public 
Its not even a feature, its simply illegal to redefine keywords. –  Georg Fritzsche Jul 5 '10 at 0:46

A dangerous secret is

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

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;
  func(b); //yeah baby
  a=b; //gotta love this
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

Template metaprogramming is.


I know somebody who defines a getter and a setter at the same time with only one method. Like this:

class foo
    int x;

    int* GetX(){
        return &x;

You can now use this as a getter as usual (well, almost):

int a = *GetX();

and as a setter:

*GetX() = 17;
Why on earth would he return int* instead of int& in that case!? –  Johann Gerell Feb 26 '10 at 9:33
No offense to you, aheld, but my down-vote is for your friend. :) There's no reason to have it return a pointer when a non-const reference will do. Additionally, there's no point in even having a getter, it's just a waste of space; make the member variable public. –  GManNickG Feb 26 '10 at 19:40
It defeats the whole point of using getters and setters by exposing the internal implementation thereby making it impossible to change the implementation later on without affecting every caller. Your friend managed to combine all the disadvantages of direct member access with all the disadvantages of getters/setters. Good work. –  Ferruccio Nov 18 '10 at 23:57

One of the most interesting grammars of any programming languages.

Three of these things belong together, and two are something altogether different...

SomeType t = u;
SomeType t(u);
SomeType t();
SomeType t;
SomeType t(SomeType(u));

All but the third and fifth define a SomeType object on the stack and initialize it (with u in the first two case, and the default constructor in the fourth. The third is declaring a function that takes no parameters and returns a SomeType. The fifth is similarly declaring a function that takes one parameter by value of type SomeType named u.

If u is a different type from SomeType, then the first one will call the conversion constructor first and then the copy constructor, whereas the second one will only call the conversion constructor. –  Eclipse Jan 7 '09 at 23:32
Yes, what a wonderful feature that is... –  j_random_hacker Jan 22 '09 at 9:30
1st is implicit call of constructor, 2nd is explicit call. Look at the following code to see the difference: #include <iostream> class sss { public: explicit sss( int ) { std::cout << "int" << std::endl; }; sss( double ) { std::cout << "double" << std::endl; }; }; int main() { sss ddd( 7 ); // calls int constructor sss xxx = 7; // calls double constructor return 0; } –  Kirill V. Lyadvinsky Jun 23 '09 at 20:04

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]

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

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,]


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";

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";

void f<>(int*) { // (d) another identical explicit specialization
  std::cout << "f(int *) another specilization\n";
+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

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.

class Empty {};

namespace std {
  // #1 specializing from std namespace is okay under certain circumstances
  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;" */
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
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
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
"It is undefined for a C++ program to add declarations or definitions to namespace std or namespaces within namespace std unless otherwise specified." ( 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." ( –  Roger Pate Feb 26 '10 at 7:48
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

The ternary conditional operator ?: requires its second and third operand to have "agreeable" types (speaking informally). But this requirement has one exception (pun intended): either the second or third operand can be a throw expression (which has type void), regardless of the type of the other operand.

In other words, one can write the following pefrectly valid C++ expressions using the ?: operator

i = a > b ? a : throw something();

BTW, the fact that throw expression is actually an expression (of type void) and not a statement is another little-known feature of C++ language. This means, among other things, that the following code is perfectly valid

void foo()
  return throw something();

although there's not much point in doing it this way (maybe in some generic template code this might come handy).


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

void functions can return void values

Little known, but the following code is fine

void f() { }
void g() { return f(); }

Aswell as the following weird looking one

void f() { return (void)"i'm discarded"; }

Knowing about this, you can take advantage in some areas. One example: void functions can't return a value but you can also not just return nothing, because they may be instantiated with non-void. Instead of storing the value into a local variable, which will cause an error for void, just return a value directly

template<typename T>
struct sample {
  // assume f<T> may return void
  T dosomething() { return f<T>(); }

  // better than T t = f<T>(); /* ... */ return t; !

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
   clC& operator=(const clC& other)
      //do some assignment stuff
      return copy(other);
   virtual clC& copy(const clC& other);

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

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

  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.


Getting rid of forward declarations:

struct global
     void main()
           a = 1;
     int a;
     void b(){}

Writing switch-statements with ?: operators:

string result = 
    a==0 ? "zero" :
    a==1 ? "one" :
    a==2 ? "two" :

Doing everything on a single line:

void a();
int b();
float c = (a(),b(),1.0f);

Zeroing structs without memset:

FStruct s = {0};

Normalizing/wrapping angle- and time-values:

int angle = (short)((+180+30)*65536/360) * 360/65536; //==-150

Assigning references:

struct ref
   int& r;
   ref(int& r):r(r){}
int b;
ref a(b);
int c;
*(int**)&a = &c;
FStruct s = {}; is even shorter. –  Constantin Oct 5 '08 at 17:43
This syntax "float c=(a(),b(),1.0f);" is useful for accenting the assigment-operation (assigment of "c"). Assigment-operations are important in programming because they are less likely to become deprecated IMO. Don't know why, might be something to do with functional programming where program state is re-assigned every frame. PS. And no, "int d = (11,22,1.0f)" will be equal to "1". Tested a minute ago with VS2008. –  AareP Nov 19 '09 at 17:29
+1 Shouldn't you be calling main? I'd suggest global().main(); and just forget about the singleton (you can just work with the temporary, which gets it's lifetime extended) –  sehe Dec 4 '11 at 1:40
I doubt assigning references is portable. I love the struct to waive forward declarations though. –  Thomas Eding Feb 23 '12 at 18:13

You can template bitfields.

template <size_t X, size_t Y>
struct bitfield
    char left  : X;
    char right : Y;

I have yet to come up with any purpose for this, but it sure as heck surprised me.

See here, where I recently suggested it for n-bit arithmetic: stackoverflow.com/questions/8309538/… –  sehe Dec 4 '11 at 1:08

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