Document #: | P2280R1 |
Date: | 2021-02-15 |
Project: | Programming Language C++ |
Audience: |
EWG |
Reply-to: |
Barry Revzin <[email protected]> |
[P2280R0] was discussed at the EWG telecon on Feb 3, 2021. The following polls were taken:
The use cases presented in P2280 are problems in C++’s specification of constexpr, and we would like to fix these problems, ideally in C++23.
SF F N A SA3 14 2 0 0 This should be a Defect Report against C++20, C++17, C++14, and C++11.
SF F N A SA3 11 4 0 0 Send P2280 to Electronic Polling, with the intent of going to Core, after getting input from MSVC and GCC implementors.
SF F N A SA8 10 1 0 0
This revision updates wording. This revision also adds discussion of the this
pointer, and extends the proposal to additional cover this
(but not arbitrary pointers)
Let’s say I have an array and want to get its size as a constant expression. In C, I had to write a macro:
But in C++, we should be able to do better. We have constexpr
and templates, so we can use them:
This seems like it should be a substantial improvement, yet it has surprising limitations:
void check(int const (¶m)[3]) {
int local[] = {1, 2, 3};
constexpr auto s0 = array_size(local); // ok
constexpr auto s1 = array_size(param); // error
}
The goal of this paper is to make that second case, and others like it, valid.
The reason is that in order for array_size(param)
to work, we have to pass that reference to param into array_size - and that involves “reading” the reference. The specific rule we’re violating is 7.7
[expr.const]/5.12:
5 An expression
E
is a core constant expression unless the evaluation ofE
, following the rules of the abstract machine ([intro.execution]), would evaluate one of the following:
The reason we violate the reference rule is due to the underlying principle that the constant evaluator has to reject all undefined behavior, so the compiler has to check that all references are valid.
This would be more obvious if our situation used pointers instead of references:
template <typename T, size_t N>
constexpr size_t array_size(T (*)[N]) {
return N;
}
void check(int const (*param)[3]) {
constexpr auto s2 = array_size(param); // error
}
This case has to be ill-formed, copying a function parameter during constant evaluation means it has to itself be a constant expression, and function parameters are not constant expressions - even in constexpr
or consteval
functions.
But if the param
case is ill-formed, why does the local
case work? An unsatisfying answer is that… there just isn’t any rule in [expr.const] that we’re violating. There’s no lvalue-to-rvalue conversion (we’re not reading through the reference in any way yet) and we’re not referring to a reference (that’s the previous rule we ran afoul of). With the param
case, the compiler cannot know whether the reference is valid, so it must reject. With the local
case, the compiler can see for sure that the reference to local
would be a valid reference, so it’s happy.
Notably, the rule we’re violating is only about references. We can’t write a function that takes an array by value, so let’s use the next-best thing: std::array
and use the standard library’s std::size
(cppref):
void check_arr_val(std::array<int, 3> const param) {
std::array<int, 3> local = {1, 2, 3};
constexpr auto s3 = std::size(local); // ok
constexpr auto s4 = std::size(param); // ok
}
If param
were a reference, the initialization of s4
would be ill-formed (for the same reason as previously), but because it’s a value, this is totally fine.
So as long as you pass all your containers around by value, you’re able to use get and use the size as a constant expression. Which is the kind of thing that’s intellectually interesting, but also wildly impractical because obviously nobody’s about to start passing all their containers around by value.
Here are few other cases, which currently are ill-formed because of this reference-to-unknown rule.
From Andrzej Krzemienski:
Another situation where being able to use a reference to a non-core-constant object is wen I am only interested in the type of the reference rather than the value of the object:
template <typename T, typename U> constexpr bool is_type(U &&) { return std::is_same_v<T, std::decay_t<U>>; }
So that I can use it like this:
auto visitor = [](auto&& v) { if constexpr(is_type<Alternative1>(v)) { // ... } else if constexpr(is_type<Alternative2>(v)) { // ... } };
I can do it with a macro:
From Jonathan Wakely:
auto rando(std::uniform_random_bit_generator auto& g) { if constexpr (std::has_single_bit(g.max() - g.min())) // ... else // ... }
The concept requires that
g.max()
andg.min()
are constexpr static member functions, so this should work. And if I did it with an object of that type, it would work. But becauseg
is a reference, it’s not usable in a constant expression. That makes it awkward to refactor code into a function (or function template), because what worked on the object itself doesn’t work in a function that binds a reference to that object.I can rewrite it as something like:
Or avoid abbreviated function syntax so I have a name for the type:
template<std::uniform_random_bit_generator G> auto rando(G& g) { if constexpr (std::has_single_bit(G::max() - G::min())) }
But it’s awkward that the first version doesn’t Just Work.
Another from me:
I have a project that has a structure like:
template <typename... Types> struct Widget { struct Config : Types::config... { template <typename T> static constexpr auto sends(T) -> bool { return std::is_base_of_v<typename T::config, Config>; } }; Config config; };
With the intent that this function makes for a nice and readable way of doing dispatch:
void do_configuration(auto& config) { // the actual type of config is... complicated if constexpr (config.sends(Goomba{})) { // do something } if constexpr (config.sends(Paratroopa{})) { // do something else } }
Except this doesn’t work, and I have to write:
void do_configuration(auto& config) { using Config = std::remove_cvref_t<decltype(config)>; if constexpr (Config::sends(Goomba{})) { // ... }
Which is not really “better.”
What all of these examples have in common is that they are using a reference to an object of type T
but do not care at all about the identity of that object. We’re either querying properties of the type, invoking static member functions, or even when invoking a non-static member function (as in std::array::size
), not actually accessing any non-static data members. The result would be the same for every object of type T
… so if the identity doesn’t change the result, why does the lack of identity cause the result to be non-constant? It’s very much constant.
this
pointerConsider the following example, very similar to one I shared earlier. Here, we need to read a constant through a member, so we write our member function two different ways (the latter using [P0847R6]):
Regular non-static member function
|
With deducing this
|
---|---|
The example on the left is ill-formed, even if we extend the rule to allow references-to-unknown. Because we don’t even have a reference here exactly, we’re accessing through this
, and one of the things we’re not allowed to evaluate as part of constant evaluation is the first bullet from [expr.const]/5:
- (5.1)
this
, except in a constexpr function that is being evaluated as part ofE
;
And here, Widget<V>::f
is not a constexpr
function. However, the example on the right is valid with the suggested rule change. Here, self
is a reference-to-unknown and value
ends up being a constexpr variable that we can read. So this works. This example wasn’t exactly what we had in mind when we wrote that paper though, and while we would be happy to keep dumping motivating use-cases into that paper… it doesn’t exactly seem like a meaningful solution to the problem. It seems pretty unsatisfactory that self.config.value
is okay while (*this).config.value
is not, when self
and (*this)
mean the same thing in this context.
It seems like there is a hierarchy of expressions in this space, which go roughly like:
this
pointerFor instance:
void f(std::array<int, 3>& r, std::array<int, 4>* p) {
static_assert(r.size() == 3); // #1
static_assert(p->size() == 4); // #2
static_assert(p[3].size() == 4); // #3
static_assert(&r == &r); // #4
}
#1
is one of the motivating examples in the paper. #2
would require dereferencing a pointer, which is similar to accessing through a reference yet isn’t exactly the same. #3
additionally requires array access and we have no idea if p
actually points to an array, much less what the size of that array would be. But both #2
and #3
generally fit the notion that these are expressions that either have a particular constant value or are undefined behavior, although #2
only requires that p
be a pointer to unknown object while #3
requires p
be a pointer to an unknown array of objects.
#4
is interesting in a different way: here this actually has to be true, but in order support that, rather than simply tracking that &r
is “pointer to known array<int, 3>
”, we have to additionally track that it is specifically a pointer to r
. This, at least in EDG, is a much bigger change (with much less commensurate value).
The problem is, while changing the specification to support #1
is largely around not rejecting the case, supporting #2
is a much more involved process. We not only have to introduce the concept of pointer-to-unknown but we also have to specify what all the operations mean. We have to say what a pointer-to-unknown means. That it dereferences into a reference-to-unknown and likewise that taking the address of a reference-to-unknown yields a pointer-to-unknown.
But then we also have to define what the various other operations on pointers to references are. What about addition and subtraction and indexing (i.e. #3
)? Equality (i.e. #4
)? Ordering? If we reject indexing, what about p[0]
?
Basically, I think supporting references-to-unknown is largely about not rejecting those cases. Similarly, supporting this
in the context of (implicit or explicit) class member access is likewise simply about not rejecting. But in order to support arbitrary pointers, there’s a whole lot of things that need to be specified. As such, the line I’m trying with this paper is to support references and specifically class member access through this
, but not arbitrary pointers.
The proposal is to allow these cases to just work. That is, if during constant evaluation, we run into a reference with unknown origin, this is still okay, we keep going. Similarly, class member access through this
.
Some operations are allowed to propagate a reference-to-unknown node (such as class member access or derived-to-non-virtual-base conversions). But most operations are definitely non-constant (such as lvalue-to-rvalue conversion, assignment, any polymorphic operations, conversion to a virtual base class, etc.). This paper is just proposing allowing those cases that work irrespective of the value of the reference or pointer (i.e. those that are truly constant), so any operation that depends on the value in any way needs to continue to be forbidden.
Notably, this paper is definitively not proposing any kind of short-circuiting evaluation. For example:
This check still must evaluate g()
, which may or may not be a constant expression in its own right, even if g().size()
is “obviously” 10. This paper is focused solely on those cases where we have an id-expression of reference or pointer type.
I’ve implemented this in EDG at least to the extent that the test cases prestend in this paper all pass, whereas previously they had all failed.
There are a few other closely related examples to consider for how to word this proposal. All of these are courtesy of Richard Smith.
We generally assume the following works:
but n
might not be in its lifetime when it’s read in the evaluation of arr
’s array bound. So we need to add wording to actaully make that work.
Then there are further lifetime questions. The following example is similar to the other examples presented earlier:
But this one is a bit different:
Here, we convert &b
to A2*
and that might be undefined behavior (as per [class.cdtor]/3). But this case seems similar enough to the earlier cases and should be allowed: b.f()
is a constant, even with a virtual base. We need to ensure then that we consider references as within their lifetimes.
If we go back to this example:
It seems reasonable to allow it, having no idea what the definition of b
is. But what if we do see the definition of b
, and it’s:
Now we know b
isn’t within its lifetime. We added more information, and turned our constant expression into a non-constant expression?
However, there’s a reasonable principle here: anything that has only one possible interpretation with defined behavior has that defined behavior for constant evaluation purposes. This is true of all the examples presented up until now.
A different case is the following:
Here, A::f
is virtual
. Which might make it seem constant, but any number of shenanigans could ensue — like placement-new-ing a derived type (of the same size) over a
. So all of these should probably remain non-constant expressions.
Perhaps the most fun example is this one:
Which every compiler currently provides different results (in order of most reasonable to least reasonable):
arr+N
is non-constant if N != 0
, and accepts with N == 0
.arr+N
is always constant (even though it sometimes has UB), but rejects reading *p
if arr+N
is out of bounds.arr+N
is always constant (even though it sometimes has UB), but always rejects reading *p
even if arr+N
is in-bounds.arr
as non-constexpr and define it constexpr, even though there is no such ruleThis, to me, seems like there should be an added rule in [expr.const] that rejects addition and subtraction to an array of unknown bound unless that value is 0. This case seems unrelated enough to the rest of the paper that I think it should just be a Core issue.
We need to strike the 7.7 [expr.const]/5.12 rule that disallows using references-to-unknown during constant evaluation, and add a new rule to reject polymorphic objects on unknown objects and taking the address of an unknown reference:
5 An expression
E
is a core constant expression unless the evaluation ofE
, following the rules of the abstract machine ([intro.execution]), would evaluate one of the following:
- (5.1)
this
, except- (5.2) […]
- (5.5) an invocation of a virtual function for an object unless the object’s dynamic type is known and either
- (5.7) […]
- (5.8) an lvalue-to-rvalue conversion unless it is applied to
- (5.9) […]
- (5.10) […]
- (5.11) an invocation of an implicitly-defined copy/move constructor or copy/move assignment operator for a union whose active member (if any) is mutable, unless the lifetime of the union object began within the evaluation of
E
;- (5.12)
an id-expression that refers to a variable or data member of reference type unless the reference has a preceding initialization and either- (5.13) in a lambda-expression, a reference to
this
or to a variable with automatic storage duration defined outside that lambda-expression, where the reference would be an odr-use;- (5.14) […]
- (5.26) a
dynamic_cast
([expr.dynamic.cast]) ortypeid
([expr.typeid]) expression on a reference bound to an object whose dynamic type is unknown or that would throw an exception;
And add a new rule to properly handle the lifetime examples shown in the previous section:
* During the evaluation of an expression
E
as a core constant expression, all id-expressions and uses of*this
that refer to an object or reference whose lifetime did not begin with the evaluation ofE
are treated as referring to a specific instance of that object or reference whose lifetime and that of all subobjects (including all union members) includes the entire constant evaluation. For such an object that is not usable in constant expressions, the dynamic type of the object is unknown. For such a reference that is not usable in constant expressions, the reference is treated as being bound to an unspecified object of the referenced type whose lifetime and that of all subobjects includes the entire constant evaluation and whose dynamic type is unknown.[Example:
template <typename T, size_t N> constexpr size_t array_size(T (&)[N]) { return N; } void use_array(int const (&gold_medal_mel)[2]) { constexpr auto gold = array_size(gold_medal_mel); // ok } constexpr auto olympic_mile() { const int ledecky = 1500; return []{ return ledecky; }; } static_assert(olympic_mile()() == 1500); // ok struct Swim { constexpr int phelps() { return 28; } virtual constexpr int lochte() { return 12; } int coughlin = 12; }; void splash(Swim& swam) { static_assert(swam.phelps() == 28); // ok static_assert((&swam)->phelps() == 28); // error: lvalue-to-conversion on a pointer not // usable in constant expressions static_assert(swam.lochte() == 12); // error: invoking virtual function on reference // with unknown dynamic type static_assert(swam.coughlin == 12); // error: lvalue-to-rvalue conversion on an object // not usable in constant expressions } extern Swim dc; extern Swim& trident; constexpr auto& x = typeid(dc); // ok: can only be typeid(Swim) constexpr auto& y = typeid(trident); // error: unknown dynamic type
- end example]
Add a note to [expr.const]/11 to make it clear that these are not permitted results:
11 An entity is a permitted result of a constant expression if it is an object with static storage duration that either is not a temporary object or is a temporary object whose value satisfies the above constraints, or if it is a non-immediate function. [ Note: A glvalue core constant expression that either refers to or points to an unspecified object is not a constant expression. - end note]
Thanks to Daveed Vandevoorde for the encouragement and help. Thanks to Richard Smith for carefully describing the correct rule on the reflector and helping provide further examples and wording. Thanks to Michael Park for pointing out the issue to me, Tim Song for explaining it, and Jonathan Wakely for suggesting I pursue it.
[P0847R6] Barry Revzin, Gašper Ažman, Sy Brand, Ben Deane. 2021-01-15. Deducing this.
https://wg21.link/p0847r6
[P2280R0] Barry Revzin. 2021-01-13. Using unknown references in constant expressions.
https://wg21.link/p2280r0