C++11 gives us a new form of metaprogramming: computation of constexpr functions. Is this form of computation Turing-complete? I am thinking that since recursion and the conditional operator (?:) are allowed in constexpr functions, it would be, but I would like someone with more expertise to confirm.
However, since the publication of the C++11 standard, the situation has changed.
The problem described in Johannes Schaub's answer to std::max() and std::min() not constexpr was reported to the C++ standardization committee as core issue 1454. At the February 2012 WG21 meeting, we decided that this was a defect in the standard, and the chosen resolution included the ability to create values of class types with pointer or reference members which designate temporaries. This allows an unbounded quantity of information to be accumulated and processed by a
In order to demonstrate the Turing-completeness of
Trunk versions of both g++ and clang implement the resolution of this core issue, but g++'s implementation currently is unable to process this code.
If we take in account restrictions of real computer - such as finite memory and finite value of MAX_INT - then, of course, constexpr (and also the whole C++) is not Turing-complete.
But if we will remove this restriction - for example, if we will think about int as a completely arbitary positive integer - then yes, constexpr part of C++ will be Turing complete. It is easy to express any partial recursive function.
0, S(n) = n+1 and selectors I_n^m(x_1, ..., x_n) = x_m and superposition obviously can be expressed using constexpr.
Primitive recursion can be done it straight way:
And for partial recursion we need a simple trick:
So we get any partial recursion function as a constexpr.