Wouldn't it be feasible for a compiler to infer constexpr automatically?

Question

constexpr permits expressions which can be evaluated at compile time to be ... evaluated at compile time.

Why is this keyword even necessary? Why not permit or require that compilers evaluate all expressions at compile time if possible?

The standard library has an uneven application of constexpr which causes a lot of inconvenience. Making constexpr the "default" would address that and likely improve a huge amount of existing code.

Answer 1

It already is permitted to evaluate side-effect-free computations at compile time, under the as-if rule.

What constexpr does is provide guarantees on what data-flow analysis a compliant compiler is required to do to detect¹ compile-time-computable expressions, and also allow the programmer to express that intent so that they get a diagnostic if they accidentally do something that cannot be precomputed.

Making constexpr the default would eliminate that very useful diagnostic ability.

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¹ In general, requiring "evaluate all expressions at compile time if possible" is a non-starter, because detecting the "if possible" requires solving the Halting Problem, and computer scientists know that this is not possible in the general case. So instead a relaxation is used where the outputs are { "Computable at compile-time", "Not computable at compile-time or couldn't decide" }. And the ability of different compilers to decide would depend on how smart their test was, which would make this feature non-portable. constexpr defines the exact test to use. A smarter compiler can still pre-compute even more expressions than the Standard test dictates, but if they fail the test, they can't be marked constexpr.

Answer 2

Note: despite the below, I admit to liking the idea of making constexpr the default. But you asked why it wasn't already done, so to answer that I will simply elaborate on mattnewport's last comment:

Consider the situation today. You're trying to use some function from the standard library in a context that requires a constant expression. It's not marked as constexpr, so you get a compiler error. This seems dumb, since "clearly" the ONLY thing that needs to change for this to work is to add the word constexpr to the definition.

Now consider life in the alternate universe where we adopt your proposal. Your code now compiles, yay! Next year you decide you to add Windows support to whatever project you're working on. How hard can it be? You'll compile using Visual Studio for your Windows users and keep using gcc for everyone else, right?

But the first time you try to compile on Windows, you get a bunch of compiler errors: this function can't be used in a constant expression context. You look at the code of the function in question, and compare it to the version that ships with gcc. It turns out that they are slightly different, and that the version that ships with gcc meets the technical requirements for constexpr by sheer accident, and likewise the one that ships with Visual Studio does not meet those requirements, again by sheer accident. Now what?

No problem you say, I'll submit a bug report to Microsoft: this function should be fixed. They close your bug report: the standard never says this function must be usable in a constant expression, so we can implement however we want. So you submit a bug report to the gcc maintainers: why didn't you warn me I was using non-portable code? And they close it too: how were we supposed to know it's not portable? We can't keep track of how everyone else implements the standard library.

Now what? No one did anything really wrong. Not you, not the gcc folks, nor the Visual Studio folks. Yet you still end up with un-portable code and are not a happy camper at this point. All else being equal, a good language standard will try to make this situation as unlikely as possible.

And even though I used an example of different compilers, it could just as well happen when you try to upgrade to a newer version of the same compiler, or even try to compile with different settings. For example: the function contains an assert statement to ensure it's being called with valid arguments. If you compile with assertions disabled, the assertion "disappears" and the function meets the rules for constexpr; if you enable assertions, then it doesn't meet them. (This is less likely these days now that the rules for constexpr are very generous, but was a bigger issue under the C++11 rules. But in principle the point remains even today.)

Lastly we get to the admittedly minor issue of error messages. In today's world, if I try to do something like stick in a cout statement in constexpr function, I get a nice simple error right away. In your world, we would have the same situation that we have with templates, deep stack-traces all the way to the very bottom of the implementation of output streams. Not fatal, but surely annoying.

This is a year and a half late, but I still hope it helps.

Answer 3

As Ben Voigt points out, compilers are already allowed to evaluate anything at compile time under the as-if rule.

What constexpr also does is lay out clear rules for expressions that can be used in places where a compile time constant is required. That means I can write code like this and know it will be portable:

constexpr int square(int x) { return x * x; }

...
int a[square(4)] = {};
...

Without the keyword and clear rules in the standard I'm not sure how you could specify this portably and provide useful diagnostics on things the programmer intended to be constexpr but don't meet the requirements.