using namespace std;

class Base
        virtual void show() { cout<<" In Base \n"; }

class Derived: public Base
       void show() { cout<<"In Derived \n"; }

int main(void)
    Base *bp = new Derived;
    bp->show();  // RUN-TIME POLYMORPHISM
    return 0;

Why does this code cause run-time polymorphism and why can not it be solved at compile time?

  • 13
    If you want compile time polymorphism, look at the curiously recurring template pattern. Dec 18, 2015 at 11:45
  • 4
    Are you asking about this simple case, or the general case? Dec 18, 2015 at 13:18
  • 14
    The general case is undecidable because it involves solving the Halting Problem (or an equivalent problem, e.g. program equivalence). It also doesn't make sense from a practical point of view because it may depend on runtime information such as user input.
    – Jens
    Dec 18, 2015 at 13:33
  • 2
    @Jens when I google why run time polymorphism involves the Halting problem, I get this SO page. Can you provide some more info?
    – Carlos
    Dec 18, 2015 at 19:05
  • 8
    @Carlos It's not runtime polymorphism in general, but the question if the compiler can figure out statically which method is called even when it does not depend on any runtime information. In this case, it basically comes down Program Equivalence or Reachability, which are both undecidable because of the Halting Problem. In the given example a compiler should have no problem to remove the dynamic dispatch.
    – Jens
    Dec 18, 2015 at 20:56

6 Answers 6


Because in the general case, it's impossible at compile time to determine what type it will be at run time. Your example can be resolved at compile time (see answer by @Quentin), but cases can be constructed that can't, such as:

Base *bp;
if (rand() % 10 < 5)
    bp = new Derived;
    bp = new Base;
bp->show(); // only known at run time

EDIT: Thanks to @nwp, here's a much better case. Something like:

Base *bp;
char c;
std::cin >> c;
if (c == 'd')
    bp = new Derived;
    bp = new Base;
bp->show(); // only known at run time 

Also, by corollary of Turing's proof, it can be shown that in the general case it's mathematically impossible for a C++ compiler to know what a base class pointer points to at run time.

Assume we have a C++ compiler-like function:

bool bp_points_to_base(const string& program_file);

That takes as its input program_file: the name of any C++ source-code text file where a pointer bp (as in the OP) calls its virtual member function show(). And can determine in the general case (at sequence point A where the virtual member function show() is first invoked through bp): whether the pointer bp points to an instance of Base or not.

Consider the following fragment of the C++ program "q.cpp":

Base *bp;
if (bp_points_to_base("q.cpp")) // invokes bp_points_to_base on itself
    bp = new Derived;
    bp = new Base;
bp->show();  // sequence point A

Now if bp_points_to_base determines that in "q.cpp": bp points to an instance of Base at A then "q.cpp" points bp to something else at A. And if it determines that in "q.cpp": bp doesn't point to an instance of Base at A, then "q.cpp" points bp to an instance of Base at A. This is a contradiction. So our initial assumption is incorrect. So bp_points_to_base can't be written for the general case.

  • 12
    Maybe reading from cin would have been a better example than rand since rand can be easily precalculated.
    – nwp
    Dec 18, 2015 at 12:56
  • 3
    you should see your rand with time , otherwise it is solvable at compile time. True I am being pedantic.
    – g24l
    Dec 18, 2015 at 14:03
  • 73
    Guys, @Paul_Evans is not writing crypto here. Just answering a question about compile-time precalculations!
    – loneboat
    Dec 18, 2015 at 17:42
  • 3
    Wow, proving things about C++! Turing was sure ahead of his time! =P
    – user541686
    Dec 19, 2015 at 4:58
  • 2
    @Mehrdad He most certainly was! The proof holds because C++ (and hence any C++ compiler which can be written in C++) is Turing-complete :P
    – Paul Evans
    Dec 19, 2015 at 6:56

Compilers routinely devirtualise such calls, when the static type of the object is known. Pasting your code as-is into Compiler Explorer produces the following assembly:

main:                                   # @main
        pushq   %rax
        movl    std::cout, %edi
        movl    $.L.str, %esi
        movl    $12, %edx
        callq   std::basic_ostream<char, std::char_traits<char> >& std::__ostream_insert<char, std::char_traits<char> >(std::basic_ostream<char, std::char_traits<char> >&, char const*, long)
        xorl    %eax, %eax
        popq    %rdx

        pushq   %rax
        movl    std::__ioinit, %edi
        callq   std::ios_base::Init::Init()
        movl    std::ios_base::Init::~Init(), %edi
        movl    std::__ioinit, %esi
        movl    $__dso_handle, %edx
        popq    %rax
        jmp     __cxa_atexit            # TAILCALL

        .asciz  "In Derived \n"

Even if you cannot read assembly, you can see that only "In Derived \n" is present in the executable. Not only has dynamic dispatch been optimized out, so has the whole base class.

  • If you want to include only the relevant parts of the assembly, the first 9 lines are the ones that matter.
    – edmz
    Dec 19, 2015 at 13:35

Why does this code cause run time polymorphism and why can not it be solved in compile time?

What makes you think that it does?

You are making a common assumption: just because the language identifies this case as using run time polymorphism does not mean that an implementation is held to dispatching at run time. The C++ Standard has a so-called "as-if" rule: the observable effects of the C++ Standard rules are described with regard to an abstract machine, and implementations are free to achieve said observable effects however they wish.

Actually, devirtualization is the general word used to speak about compiler optimizations aiming at resolving calls to virtual methods at compile-time.

The goal is not so much to shave off the nearly unnoticeable virtual call overhead (if branch prediction works well), it is about removing a black box. The best gains, in terms of optimizations, are keyed on inlining the calls: this opens up constant propagation and a whole lot of optimization, and inlining can only be achieved when the body of the function being called is known at compile-time (since it involved removing the call and replacing it by the function body).

Some devirtualization opportunities:

  • a call to a final method or a virtual method of a final class are trivially devirtualized
  • a call to a virtual method of a class defined in an anonymous namespace may be devirtualized if that class is a leaf in the hierarchy
  • a call to a virtual method via a base class may be devirtualized if the dynamic type of the object can be established at compile time (which is the case of your example, with the construction being in the same function)

For the state of the art, however, you will want to read Honza Hubička's Blog. Honza is a gcc developer and last year he worked on speculative devirtualization: the goal is to compute the probabilities of the dynamic type being either A, B or C and then speculatively devirtualize the calls somewhat like transforming:

Base& b = ...;


Base& b = ...;
if      (b.vptr == &VTableOfA) { static_cast<A&>(b).call(); }
else if (b.vptr == &VTableOfB) { static_cast<B&>(b).call(); }
else if (b.vptr == &VTableOfC) { static_cast<C&>(b).call(); }
else                           { b.call(); } // virtual call as last resort

Honza did a 5-part post:

  • Aren't most virtual function calls roughly equivalent to the chained if statements you have there anyway (albeit more of a switch/jumptable-type structure)? Or is that just to be able to provide inlined definitions of some of the possibilities?
    – JAB
    Dec 18, 2015 at 15:04
  • @JAB: I am not too aware of the exact hardware cost of "if" vs "switch" (as virtual calls are similar to switches in that multiple targets exist); as you noted though the real gain is that the static_cast<A&>(b).call(); statement (and its siblings) can be inlined, which in turn opens up a variety of optimizations. Also, note that the reason I mentioned computing the probabilities of getting "A", "B" or "C" is that (1) only those derived classes above a certain probability threshold will appear like so (to avoid bloat) and (2) they can be ordered from the best probability to the worst. Dec 18, 2015 at 15:20
  • Indirect branches can have more of an impact on highly pipelined architectures than conditional branches due to branch prediction being trickier to implement, so depending on compiler/optimization level/features supported by the target architecture, some switch statements will indeed get compiled to chained ifs (or some combination of conditionals+jumptables). On the other hand, it's also possible for a compiler to transform a series of chained ifs into a simple indirect branch if the conditions are right.
    – JAB
    Dec 18, 2015 at 15:38
  • @JAB: Thanks for the tip! Dec 18, 2015 at 15:49
  • It's nice to know that G++ might soon catch up with 1980s Smalltalk technology :-D Dec 18, 2015 at 16:53

There are many reasons why compilers cannot in general replace the runtime decision with static calls, mostly because it involves information not available at compile time, e.g. configuration or user input. Aside from that, I want to point out two additional reasons why this is not possible in general.

First, the C++ compilation model is based on separate compilation units. When one unit is compiled, the compiler only knows what is defined in the source file(s) being compiled. Consider a compilation unit with a base class and a function taken a reference to the base class:

struct Base {
    virtual void polymorphic() = 0;
void foo(Base& b) {b.polymorphic();}

When compiled separately, the compiler has no knowledge about the types that implement Base and thus cannot remove the dynamic dispatch. It also not something we want because we want to able to extend the program with new functionality by implementing the interface. It may be possible to do that at link time, but only under the assumption that the program is fully complete. Dynamic libraries can break this assumption, and as can be seen in the following, there will always be cases were it is not possible at all.

A more fundamental reason comes from Computability theory. Even with complete information, it is not possible to define an algorithm that computes if a certain line in a program will be reached or not. If you could you could solve the Halting Problem: for a program P, I create a new program P' by adding an additional line to the end of P. The algorithm would now be able to decide if that line is reached, which solves the Halting Problem.

Being unable to decide in general means that compilers cannot decide which value is assigned to variables in general, e.g.

bool someFunction( /* arbitrary parameters */ ) {
     // ...

// ...
Base* b = nullptr;
if (someFunction( ... ))
    b = new Derived1();
    b = new Derived2();


Even when all parameters are known at compile time, it is not possible to prove in general which path through the program will be taken and which static type b will have. Approximations can and are made by optimizing compilers, but there are always cases where it does not work.

Having said that, C++ compilers try very hard to remove dynamic dispatch because it opens many other optimization chances mainly from being able to inline and propagate knowledge through the code. If you are interesting, you can find an interesting serious of blog posts for the GCC devirtualization implementation.


That could easily be resolved at compile time if the optimizer chose to do so.

The standard specifies the same behavior as if the run-time polymorphism had occurred. It does not specific that be achieved through actual run-time polymorphism.


Basically the compiler should be able to figure out that this should not result in runtime polymorphism in your very simple case. Most probably there are compilers that actually do that but that is mostly a conjecture.

The problematic is the General case when you are actually building a complex, and apart of the cases with library dependencies, or complexity of analysing post-compilation multiple compilation units, which would require keeping multiple versions of the same code, which would blow out AST generation, the real issue boils down to decidability and the halting problem.

The latter does not permit to solve the problem if a call can be devirtualized in the general case.

The halting problem is to decide if a program given an input will halt ( we say the program-input pair halts). It is known that there is no general algorithm , e.g. a compiler, that solves for all possible program-input pairs.

In order for the compiler to decide for any program if a call should be made virtual or not, it should be able to decide that for all possible program-input pairs.

In order to do that the compiler would need to have an algorithm A that decides that given program P1 and program P2 where P2 makes a virtual call, then program P3 { while( {P1,I} != {P2,I} ) } halts for any input I.

Thus the compiler to be able to figure out all possible devirtualization should be able to decide that for any pair (P3,I) over all possible P3 and I;which is undecidable for all because A does not exist. However it can be decided for specific cases that can be eye-balled.

That is why in your case the call can be devirtualized, but not any case.

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