Is it possible to produce a compile-time boolean value based on whether or not a C++11 expression is a constant expression (i.e. constexpr) in C++11? A few questions on SO relate to this, but I don't see a straight answer anywhere.

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    gcc has __builtin_constant_p(), gcc.gnu.org/onlinedocs/gcc-4.1.2/gcc/Other-Builtins.html Nov 8 '12 at 23:10
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    @user643722 Sorry, my comment was missing "or". There are two cases: true if f has a constexpr, false otherwise specifier AND true if f has a constexpr and fe(x) is actually const. Which do you want the weaker or the stronger condition?
    – pmr
    Nov 8 '12 at 23:23
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    "I.e." means literally "that is." Translate it as "which is to say." Did you mean "e.g."? Nov 8 '12 at 23:35
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    @JiveDadson: No, I do mean i.e. Nov 8 '12 at 23:42
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    @user643722 So you want specifically to know if the value is declared with the keyword constexpr? That is what "i.e." implies, but I do not think most people would consider "a constant expression" and "constexpr" to be synonymous. Nov 8 '12 at 23:50

I once wrote it (EDIT: see below for limitations and explanations). From https://stackoverflow.com/a/10287598/34509 :

template<typename T> 
constexpr typename remove_reference<T>::type makeprval(T && t) {
  return t;

#define isprvalconstexpr(e) noexcept(makeprval(e))

However there are many kinds of constant expressions. The above answer detects prvalue constant expressions.


The noexcept(e) expression gives false iff e contains

  • a potentially evaluated call to a function that does not have a non-throwing exception-specification unless the call is a constant expression,
  • a potentially evaluated throw expression,
  • a potentially evaluated throwable form of dynamic_cast or typeid.

Note that the function template makeprval is not declared noexcept, so the call needs to be a constant expression for the first bullet not to apply, and this is what we abuse. We need the other bullets to not apply aswell, but thanksfully, both a throw and a throwable dynamic_cast or typeid aren't allowed in constant expressions aswell, so this is fine.


Unfortunately there is a subtle limitation, which may or may not matter for you. The notion of "potentially evaluated" is much more conservative than the limits of what constant expressions apply. So the above noexcept may give false negatives. It will report that some expressions aren't prvalue constant expressions, even though they are. Example:

constexpr int a = (0 ? throw "fooled!" : 42);
constexpr bool atest = isprvalconstexpr((0 ? throw "fooled!" : 42));

In the above atest is false, even though the initialization of a succeeded. That is because for being a constant expression, it suffices that the "evil" non-constant sub-expressions are "never evaluated", even though those evil sub-expressions are potentially-evaluated, formally.

  • It is not part of the type. You cannot use the proposed method.
    – Sergey K.
    Nov 9 '12 at 9:16
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    @sergey i dont understand. can you explain why my method does not work? Nov 9 '12 at 9:24
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    @JohannesSchaub-litb: I'm interested in why your solution works with GCC, but fails with Clang. For example, unlike GCC, Clang reckons integer literals, or constexpr integer variables, are not "prvalue" constant expressions (according to your test). Which compilers did you try? Nov 9 '12 at 9:48
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    @user thanks for your report. i will try to figure out why it fails on clang later today. Nov 9 '12 at 9:50
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    @litb This doesn't work on Clang yet because Clang doesn't check whether a call is a constant expression when deciding whether it is noexcept. May 20 '13 at 6:16

As of 2017, is_constexpr is not possible in C++11. That sounds like an odd thing to say, so let me explain a bit of the history.

First, we added this feature to resolve a defect: http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_defects.html#1129

Johannes Schaub - litb posted a constexpr detection macro that relied on the provision that constant expressions are implicitly noexcept. This worked in C++11, but was never implemented by at least some compilers (for instance, clang). Then, as part of C++17, we evaluated Removing Deprecated Exception Specifications from C++17. As a side-effect of that wording, we accidentally removed that provision. When the Core Working Group discussed adding the provision back in, they realized that there were some serious problems with doing so. You can see the full details in the LLVM bug report. So rather than adding it back in, we decided to consider it a defect against all versions of standard and retroactively removed it.

The effect of this is that there is, to my knowledge, no way to detect whether an expression is usable as a constant expression.

  • Is there a plan to actually include is_constexpr into C++?
    – geza
    Nov 28 '17 at 19:25
  • @David Stone That's a pity, but can't fault your answer. Max kudos for taking the time. Nov 28 '17 at 19:48
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    I am currently working on a proposal that would allow implementing is_constexpr as a macro (must be a macro to avoid side-effects). Hopefully it will be discussed at the next committee meeting. Nov 30 '17 at 0:32
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    @CharlesLWilcox: At the risk of killing the joke by explaining it, we were considering adding something in to the next standard, and on further review, removed it from old standards instead. See: the second panel of that comic. Dec 14 '17 at 0:43
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    I have a proposal that would make this possible. It is targeted at C++23. I will post as an answer if it gets accepted. (Note that some of the formatting is messed up on GitHub) Jul 4 '19 at 2:36

Yes, this is possible. One way to do it (which is valid even with the recent noexcept changes) is to take advantage of the C++11 narrowing conversion rules:

A narrowing conversion is an implicit conversion [...] from an integer type or unscoped enumeration type to an integer type that cannot represent all the values of the original type, except where the source is a constant expression whose value after integral promotions will fit into the target type.

(emphasis mine). List initialization generally disallows narrowing conversions, and when combined with SFINAE we can build gadgets for detecting whether an arbitrary expression is a constant expression:

// p() here could be anything
template<int (*p)()> std::true_type is_constexpr_impl(decltype(int{(p(), 0U)}));
template<int (*p)()> std::false_type is_constexpr_impl(...);
template<int (*p)()> using is_constexpr = decltype(is_constexpr_impl<p>(0));

constexpr int f() { return 0; }
int g() { return 0; }

Live demonstration.

The key here is that int{(expr, 0U)} contains a narrowing conversion from unsigned int to int (and thus is ill-formed), unless expr is a constant expression, in which case the entire expression (expr, 0U) is a constant expression whose evaluated value fits into the type int.


The following is an implementation of is_constexpr for functions, not for arbitrary expressions, for C++11 and C++17. It requires the arguments to the function you want to test to be default constructible, though.

#include <type_traits>

struct A {};  // don't make it too easy, use a UDT

          A f1(A a) { return a; }  // is_constexpr -> false
constexpr A f2(A a) { return a; }  // is_constexpr -> true

// The following turns anything (in our case a value of A) into an int.
// This is necessary because non-type template arguments must be integral 
// (likely to change with C++20).
template <class T> constexpr int make_int(T &&) { return 0; }

// Helper to turn some function type (e.g. int(float)) into a function
// pointer type (e.g. int (*)(float)).
template <class T> struct signature_from;
template <class R, class... Args> struct signature_from<R(Args...)> {
    using type = R(*)(Args...);

// See std::void_t for the idea. This does it for ints instead of types.
template <int...> using void_from_int = void;

// The fallback case: F is not a function pointer to a constexpr function
template <class T, typename signature_from<T>::type F, class = void_from_int<>>
struct is_constexpr {
    static constexpr bool value = false;
// If void_from_int<make_int(F(Args()...))> doesn't lead to a substitution
// failure, then this is the preferred specialization. In that case F must
// be a function pointer to a constexpr function. If it is not, it could
// not be used in a template argument.
template <class R, class... Args, typename signature_from<R(Args...)>::type F>
struct is_constexpr<R(Args...), F, void_from_int<make_int(F(Args()...))>>
    static constexpr bool value = true;

// proof that it works:
static_assert(!is_constexpr<A(A), f1>::value, "");
static_assert( is_constexpr<A(A), f2>::value, "");

#if __cplusplus >= 201703
// with C++17 the type of the function can be deduced:
template<auto F> struct is_constexpr2 : is_constexpr<std::remove_pointer_t<decltype(F)>, F> {};

static_assert(!is_constexpr2<f1>::value, "");
static_assert( is_constexpr2<f2>::value, "");

See it in action at https://godbolt.org/g/rdeQme.

  • Your code fails to compile on MSVC (you can check with the latest version of goldbolt which at the time of me writing this is 19.21).
    – lightxbulb
    Jul 3 '19 at 11:26
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    @lightxbulb Looks like a bug in MSVC.
    – Vir
    Oct 2 '19 at 14:57

C++20 added std::is_constant_evaluated()

This allows checking if a certain expression is a constant evaluated expression, i.e. being evaluated at compile time.

Usage example:

constexpr int foo(int num) {
    // below is true in case the condition is being evaluated at compile time
    // side note, using: if constexpr (std::is_constant_evaluated())
    // would be evaluated always to true, so you should use a simple if!
    if (std::is_constant_evaluated()) {
        return foo_compiletime(num);
    else {
        return foo_runtime(num);

int main() {
    constexpr auto t1 = foo(6); // reaches foo_compiletime
    const auto t2 = foo(6);     // reaches foo_compiletime
    int n = rand() % 10;
    const auto t3 = foo(n);     // reaches foo_runtime

    auto t4 = foo(6); // unfortunately, reaches foo_runtime

The last call in the example above would reach foo_runtime, since the call is not within a constant expression context (the result is not being used as a constant expression, see also this SO answer).

This may lead to undesired pessimization, compared to the case of leaving the decision to the user, who may call:

    auto t4 = foo_compiletime(6);

And the compiler is allowed to perform the operations inside foo_compiletime at compile time, if it is declared as constexpr function, or would be obliged to do that if it is declared consteval. However, once we leave the decision to the compiler, we will reach foo_runtime, unless we explicitly direct the compiler to go for foo_compiletime, by taking the result into a const, constexpr or constinit variable. Which then, in a way, omits the value of having one function for both scenarios, if the user is required to help the compiler peek the right path.

Another possible option for the call to be optimized, is:

    constexpr auto temp = foo(6); // foo_compiletime
    auto t4 = temp;

But again, we require the user to be aware of the inner behavior of foo, which is not exactly what we want to achieve.

See the pessimization in this code.

See more on that in this great blog post on the subject.

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