[PATCH 02/10] compiler.h: add is_const() as a replacement of __is_constexpr()

Sat Dec 7 12:24:16 UTC 2024

On Sat. 7 Dec. 2024 at 20:19, David Laight <David.Laight at aculab.com> wrote:
> From: Vincent Mailhol
> > Sent: 07 December 2024 07:43
> ...
> > > So maybe the slightly long lines:
> > > #define const_true(x) _Generic(0 ? (void *)((x) + 0 ? 0L : 1L) : (char *)0, char *: 1, void *: 0)
> > > #define const_expr(x) _Generic(0 ? (void *)((x) + 0 ? 0L : 0L) : (char *)0, char *: 1, void *: 0)
>
> Clearly they can be implemented in terms of a common define.
> But I don't see a need for a const_zero() and nested expansions make extra
> work for the compiler.
>
> >
> > This still throws a -Wnull-pointer-arithmetic on clang on const_expr(NULL):
> >   https://godbolt.org/z/vo5W7efdE
>
> I was worried about that one.
>
> > I just do not see a method to silence that one. So three options:
> >
> >   1. is_const() does not accept pointers and throws a constraint violation:
> >        #define is_const(x) __is_const_zero(0 * (x))
> >      This is my current patch.
>
> Is that going to affect things like const_true(x << y)?

No warnings for const_true(x << y). See by yourself:

  https://godbolt.org/z/v79x3dnor

> Disallowing that seems counter-productive.
> (Remember it might be passed into a #define that is then
> checking its argument for being constant.)

I understand how a static inline may use __builtin_constant_p() to
check if its argument is NULL. But I am having a hard time
understanding how this would look like with macros and with
is_const().

Do you know one real life example where you have to pass NULL to a
function like macro which can not be written as a static inline
function?

And if that real life use case does not exist, then disallowing it
looks sane: it will push the developper to do the right thing: write a
static inline with __builting_constant_p().

> >   2. is_const() accept pointers but is_const(NULL) returns false:
> >        #define is_const(x) __is_const_zero((x) != (x))
> >      This keeps the current __is_constexpr() behaviour.
>
> No good - expands everything twice.

And? __is_const_zero() does not evaluate its arguments, so no side effect:

  https://godbolt.org/z/W988P4v9e

Or am I missing something else?

> >   3. is_const() accepts pointers and is_const(NULL) return true:
> >
> >        #define const_expr(x) _Generic(0 ? (void *)((x) + 0 ? 0L : 0L)
> > : (char *)0, char *: 1, void *: 0)
> >
> >      David's latest proposal, it requires to remove the
> >      -Wnull-pointer-arithmetic clang warning.
>
> Only for const_expr(NULL) - and since clang gets that wrong
> maybe the warning is a good thing.
>
> You can just add:
> #define const_NULL(ptr) const_true(!(ptr))
> Probably the only place where you actually want to test for zero.

Which goes back to my first point: if we have to declare const_NULL(),
then we probably do not want is_const() to accept NULL so that the
user sees the mismatch (and I am not acknowledging that we need
const_NULL(): as long as no use case arize, no need for it).

> > I vote for 1. or 2. (with a preference for 1.). IMHO, we are just
> > adding an unreasonable level of complexity for making the macro treat
> > NULL as an integer. Would someone find a solution for 3. that does not
> > yield a warning, then why not. But if we have to remove a compiler
> > check for a theoretical use case that does not even exist in the
> > kernel, then it is not worth the trade off.
> >
> > Concerning is_const(var << 2), the patch I submitted works fine as-is
> > with all scalars including that (var << 2):
> >
> >   https://godbolt.org/z/xer4aMees
> >
> > And can we ignore the case (!(var << 2))? This is not a warning
> > because of the macro, but because of the caller! If I do any of:
> >
> >           if (!(var << 2)) {}
> >           (void)__builtin_constant_p(!(var << 2));
> >
> > I also got the warning. The point is that the macro should not
> > generate *new* warnings. If the given argument already raises a
> > warning, it is the caller's responsibility to fix.
>
> Except it could easily happen way inside some other expansion.
> Perhaps someone optimises frobnicate(x) for constant input.
> Suddenly frobnicate(!(var << 2)) generates a compile error.

Then, that person will see that compile error and will modify
frobnicate() to remove the compile error. End of the story.

My point is simple: if the use case you are mentioning is valid, why
did it never collide with __builtin_constant_p() that we have been
using for many years?

And I am sure that there are hundreds of examples of macro that will
either pass their argument as-is to an if() or to the ternary operator
without accounting for if their input is (!(var << 2)). So why did not
these collide?

Yours sincerely,
Vincent Mailhol