74

P0292R1 constexpr if has been included, on track for C++17. It seems useful (and can replace use of SFINAE), but a comment regarding static_assert being ill-formed, no diagnostic required in the false branch scares me:

Disarming static_assert declarations in the non-taken branch of a
constexpr if is not proposed.

void f() {
  if constexpr (false)
    static_assert(false);   // ill-formed
}

template<class T>
void g() {
  if constexpr (false)
    static_assert(false);   // ill-formed; no 
               // diagnostic required for template definition
}

I take it that it's completely forbidden to use static_assert inside constexpr if (at least the false / non-taken branch, but that in practice means it's not a safe or useful thing to do).

How does this come about from the standard text? I find no mentioning of static_assert in the proposal wording, and C++14 constexpr functions do allow static_assert (details at cppreference: constexpr).

Is it hiding in this new sentence (after 6.4.1) ? :

When a constexpr if statement appears in a templated entity, during an instantiation of the enclosing template or generic lambda, a discarded statement is not instantiated.

From there on, I assume that it is also forbidden, no diagnostic required, to call other constexpr (template) functions which somewhere down the call graph may call static_assert.

Bottom line:

If my understanding is correct, doesn't that put a quite hard limit on the safety and usefulness of constexpr if as we would have to know (from documentation or code inspection) about any use of static_assert? Are my worries misplaced?

Update:

This code compiles without warning (clang head 3.9.0) but is to my understanding ill-formed, no diagnostic required. Valid or not?

template< typename T>
constexpr void other_library_foo(){
    static_assert(std::is_same<T,int>::value);
}

template<class T>
void g() {
  if constexpr (false)
    other_library_foo<T>(); 
}

int main(){
    g<float>();
    g<int>();
}
12
  • 1
    It's ill-formed because the condition is false. Not because it's inside a constexpr if...
    – user253751
    Jul 11, 2016 at 10:42
  • 3
    @immibis. It's clear that this is all about the non-taken branch, so I don't understand what you mean specifically. Care to elaborate and interpret in terms of the bottom line question? Jul 11, 2016 at 10:59
  • 3
    @cpplearner, Done that, but it does not add add much. The question is about what the standard say and its implications. Jul 11, 2016 at 11:51
  • 1
    Currently there's no standard or draft standard that contains the wording for if constexpr, and P0292R2, the paper that got accepted, is also not publicly available yet.
    – cpplearner
    Jul 11, 2016 at 12:36
  • 1
    @immibis: "But constexpr if(false) removes the code inside it." That's the thing: it doesn't remove the code inside the not taken branch. It makes them into discarded statements. There's a difference. Jul 11, 2016 at 14:05

8 Answers 8

46

This is talking about a well-established rule for templates - the same rule that allows compilers to diagnose template<class> void f() { return 1; }. [temp.res]/8 with the new change bolded:

The program is ill-formed, no diagnostic required, if:

  • no valid specialization can be generated for a template or a substatement of a constexpr if statement ([stmt.if]) within a template and the template is not instantiated, or
  • [...]

No valid specialization can be generated for a template containing static_assert whose condition is nondependent and evaluates to false, so the program is ill-formed NDR.

static_asserts with a dependent condition that can evaluate to true for at least one type are not affected.

5
  • Thank you especially for the draft link. It makes sense as evaluating invalid templates can be arbitrarily hard. Jul 12, 2016 at 6:34
  • Thanks again. Accepted. It's worth noting that the lines you quoted are in the original proposal I linked to, but I missed them. Jul 12, 2016 at 19:42
  • Helper to make false template parameter dependet:template < typename > constexpr bool false_c = false; Jun 16, 2017 at 20:47
  • However, and I don't know if that is a compiler bug or what is it, but, I had a function which different if constexpr statements that does depend on the template, and a static_assert(false) in the last else case. Since the static_assert won't be evaluated unless the other if constexpr statements fails, and thus, since the evaluation of the static_assert depends (indirectly) on the type, I think the code shouldn't be ill-formed, because there's "possible inputs" that doesn't trigger the static_assert.
    – ABu
    Oct 27, 2017 at 3:58
  • @Peregring-lk It is ill-formed NDR, because "substatements of a constexpr if statements" are also affected. It is not (only) about the constexpr if statement as a whole. Sep 16, 2020 at 4:46
38

C++20 makes static_assert in the else branch of if constexpr much shorter now, because it allows template lambda parameters. So to avoid the ill-formed case, we can now define a lambda with a bool template non-type parameter that we use to trigger the static_assert. We immediately invoke the lambda with (), but since the lambda won't be instantiated if its else branch is not taken, the assertion will not trigger unless that else is actually taken:

template<typename T>
void g()
{
    if constexpr (case_1)
        // ...
    else if constexpr (case_2)
        // ...
    else
        []<bool flag = false>()
            {static_assert(flag, "no match");}();
}
6
  • 7
    In C++17 one can define a template function outside: template<bool flag = false> void static_no_match() { static_assert(flag, "no match"); } and then use static_no_match() in the else branch.
    – cxxl
    Nov 27, 2020 at 8:35
  • 17
    In C++17 we can just make the condition dependent on the template parameter, like static_assert(!sizeof(T), "no match");. See it live
    – Ruslan
    May 24, 2021 at 18:15
  • 4
    "else" branch looks ugly with this lambda.
    – korst1k
    Nov 5, 2021 at 17:30
  • 3
    I’m not at all sure that this evades the IFNDR rule: it’s still the case that no valid specialization of the substatement exists, although one would have to reason out whether the validity of the chosen specialization of the lambda’s operator() counted for that purpose. Nov 11, 2021 at 4:03
  • 9
    This answer is referenced in the P2593 committee paper where it's described as "terrible and wrong". That paper has been accepted into C++23 and will allow static_assert(false).
    – interjay
    Feb 15, 2023 at 9:51
10

Edit: I'm keeping this self-answer with examples and more detailed explanations of the misunderstandings that lead to this questions. The short answer by T.C. is strictly enough.

After rereading the proposal and on static_assert in the current draft, and I conclude that my worries were misguided. First of all, the emphasis here should be on template definition.

ill-formed; no diagnostic required for template definition

If a template is instantiated, any static_assert fire as expected. This presumably plays well with the statement I quoted:

... a discarded statement is not instantiated.

This is a bit vague to me, but I conclude that it means that templates occurring in the discarded statement will not be instantiated. Other code however must be syntactically valid. A static_assert(F), [where F is false, either literally or a constexpr value] inside a discarded if constexpr clause will thus still 'bite' when the template containing the static_assert is instantiated. Or (not required, at the mercy of the compiler) already at declaration if it's known to always be false.

Examples: (live demo)

#include <type_traits>

template< typename T>
constexpr void some_library_foo(){
    static_assert(std::is_same<T,int>::value);
}

template< typename T>
constexpr void other_library_bar(){
    static_assert(std::is_same<T,float>::value);
}

template< typename T>
constexpr void buzz(){
    // This template is ill-formed, (invalid) no diagnostic required,
    // since there are no T which could make it valid. (As also mentioned
    // in the answer by T.C.).
    // That also means that neither of these are required to fire, but
    // clang does (and very likely all compilers for similar cases), at
    // least when buzz is instantiated.
    static_assert(! std::is_same<T,T>::value);
    static_assert(false); // does fire already at declaration
                          // with latest version of clang
}

template<class T, bool IntCase>
void g() {
  if constexpr (IntCase){
    some_library_foo<T>();

    // Both two static asserts will fire even though within if constexpr:
    static_assert(!IntCase) ;  // ill-formed diagnostic required if 
                              // IntCase is true
    static_assert(IntCase) ; // ill-formed diagnostic required if 
                              // IntCase is false

    // However, don't do this:
    static_assert(false) ; // ill-formed, no diagnostic required, 
                           // for the same reasons as with buzz().

  } else {
    other_library_bar<T>();
  }      
}

int main(){
    g<int,true>();
    g<float,false>();

    //g<int,false>(); // ill-formed, diagnostic required
    //g<float,true>(); // ill-formed, diagnostic required
}

The standard text on static_assert is remarkably short. In standardese, it's a way to make the program ill-formed with diagnostic (as @immibis also pointed out):

7.6 ... If the value of the expression when so converted is true, the declaration has no effect. Otherwise, the program is ill-formed, and the resulting diagnostic message (1.4) shall include the text of the string-literal, if one is supplied ...

2
  • 3
    A few years passed, do you happen to know a better solution? static_assert(IntCase) is very inconvenient for complex nest if-else. I really wish to call static_assert(false) within some else.
    – javaLover
    Mar 5, 2019 at 8:13
  • The phrase "ill-formated" is ill-formed. (No pun intended)
    – L. F.
    May 28, 2019 at 12:19
7

The most concise way I've come across to work-around this (at least in current compilers) is to use !sizeof(T*) for the condition, detailed by Raymond Chen here. It's a little weird, and doesn't technically get around the ill-formed problem, but at least it's short and doesn't require including or defining anything. A small comment explaining it may assist readers:

template<class T>
void g() {
  if constexpr (can_use_it_v<T>) {
    // do stuff
  } else {
    // can't use 'false' -- expression has to depend on a template parameter
    static_assert(!sizeof(T*), "T is not supported");
  }
}

The point of using T* is to still give the proper error for incomplete types.

I also came across this discussion in the old isocpp mailing list which may add to this discussion. Someone there brings up the interesting point that doing this kind of conditional static_assert is not always the best idea, since it cannot be used to SFINAE-away overloads, which is sometimes relevant.

5
  • 4
    It’s still IFNDR to have a branch of a constexpr if that’s invalid for all instantiations. Nov 11, 2021 at 3:59
  • Is it an ill-formed expression that all the compilers chose to not implement? seems to work as expected on all 3 major ones. I believe by making it type-dependent, it delays the static_assert until after if constexpr is resolved.
    – golvok
    Nov 11, 2021 at 18:02
  • 2
    That’s what “no diagnostic required” means—the implementation might or might not do enough analysis to determine that it’s always invalid. “Delaying” the static_assert may be a thing that can happen in (today’s) real compilers, but it doesn’t mean anything formally at all. Nov 11, 2021 at 18:08
  • Thanks for clarifying my understanding! You're saying that some day, a compiler may do a value range analysis earlier and see that it is always false. Could go either way I guess, with either the implementers wanting to do more analysis (like they do in some of the UB cases), or the committee specifying that this is okay (or an alternative). The desire to write asserts like this seem to come up reasonably often.
    – golvok
    Nov 11, 2021 at 20:49
  • 2
    The committee has considered providing an idiom here. They’ve also informally considered restricting the scope of the problem, because technically a compiler can also arbitrarily miscompile a program that does this. Nov 11, 2021 at 21:24
3

This has been found to be a defect, CWG 2518. Static asserts now are ignored in template declarations, so now are delayed until instantiation. Failing static asserts are no longer ill-formed no diagnostic required during template resolution.

It is being applied to all C++ modes in clang and GCC 13.

1

A comma expression can make the static_assert condition dependent on template arguments:

  #include <type_traits>

  template<typename T>
  constexpr int func(T x)
  {
    if constexpr(std::is_same_v<T, int>){
      return x;
    } else {
      static_assert((sizeof(T), false), "Bad template argument");
      return 0;
    }
   }

Or you can make a dependent expression which is always false:

      static_assert(sizeof(T) == 0, "Bad template argument");
0

Your self-answer and possibly the one by T.C. are not quite correct.

First of all, the sentence "Both two static asserts will fire even though within if constexpr" is not correct. They won't because the if constexpr condition depends on a template parameter.
You can see that if you comment out the static_assert(false) statements and the definition of buzz() in your example code: static_assert(!IntCase) won't fire and it will compile.

Furthermore, things like AlwaysFalse<T>::value or ! std::is_same_v<T, T> are allowed (and have no effect) inside a discarded constexpr if, even if there's no T for which they evaluate to true.
I think that "no valid specialization can be generated" is bad wording in the standard (unless cppreference is wrong; then T.C. would be right). It should say "could be generated", with further clarification of what is meant by "could".

This is related to the question whether AlwaysFalse<T>::value and ! std::is_same_v<T, T> are equivalent in this context (which is what the comments to this answer are about).
I would argue that they are, since it's "can" and not "could" and both are false for all types at the point of their instantiation.
The crucial difference between std::is_same and the non-standard wrapper here is that the latter could theoretically be specialized (thanks, cigien, for pointing this out and providing the link).

The question whether ill-formed NDR or not also crucially depends on whether the template is instantiated or not, just to make that entirely clear.

10
  • Would you care to explain your point more? Most of the answers in the question you link to conclude that a non std wrapper is required. Such as stackoverflow.com/a/53945555/1149664 Mar 21, 2020 at 20:17
  • No, as far as I see they only ever speak of a "type-dependent" expression, i.e. an expression that depends on T. Mar 23, 2020 at 16:50
  • It works pretty nice, without warning on gcc or clang. wandbox.org/permlink/b7DMBGyaFj7V2Nc7 Jun 19, 2020 at 5:28
  • This is not correct. It would be fine if specializations of is_same_v could exist, but "The behavior of a program that adds specializations for is_same or is_same_v (since C++17) is undefined.".
    – cigien
    Sep 7, 2020 at 13:46
  • @cigien It's not about adding specializations for is_same. The standard one serves this purpose just fine. (So would any other expression that always yields false but depends on T.) Sep 8, 2020 at 14:35
-3

My solution is:

if constexpr (is_same_v<T,int>)
  // ...
else if constexpr (is_same_v<T,float>)
  // ...
else
  static_assert(std::is_same_v<T, void> && !std::is_same_v<T, void>, "Unsupported element type.");
1
  • This is "ill formed, no diagnostics required". Read other answers why.
    – Osyotr
    Nov 27, 2022 at 15:39

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