Consider these two approaches that can represent an "optional int":

using std_optional_int = std::optional<int>;
using my_optional_int = std::pair<int, bool>;

Given these two functions...

auto get_std_optional_int() -> std_optional_int 
    return {42};

auto get_my_optional() -> my_optional_int 
    return {42, true};

...both g++ trunk and clang++ trunk (with -std=c++17 -Ofast -fno-exceptions -fno-rtti) produce the following assembly:

        mov     rax, rdi
        mov     DWORD PTR [rdi], 42
        mov     BYTE PTR [rdi+4], 1

        movabs  rax, 4294967338 // == 0x 0000 0001 0000 002a

live example on godbolt.org

Why does get_std_optional_int() require three mov instructions, while get_my_optional() only needs a single movabs? Is this a QoI issue, or is there something in std::optional's specification preventing this optimization?

Also please note that users of the functions might be completely optimized out regardless:

volatile int a = 0;
volatile int b = 0;

int main()
    a = get_std_optional_int().value();
    b = get_my_optional().first;

...results in:

        mov     DWORD PTR a[rip], 42
        xor     eax, eax
        mov     DWORD PTR b[rip], 42
  • 6
    optional is returned through a hidden pointer, meaning the type definition contains something prohibiting returning it through a register. – Jester Oct 3 '17 at 12:00
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    The obvious difference is that std::pair is an aggregate, while std::optional is not. Don't know if it should have an effect, but ya' know... – StoryTeller Oct 3 '17 at 12:08
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    Same problem with boost::optional, on any version of GCC, no fancy C++17 required for demo: godbolt.org/g/MV14mr – John Zwinck Oct 3 '17 at 12:12
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    The aggregate vs non-aggregate typing, the SYS V x64 ABI and the fact that 4294967338 is 0x10000002a should make this clear. – Margaret Bloom Oct 3 '17 at 12:21
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    @WojciechMigda folly::Optional doesn't have the necessary magic to make its special member functions conditionally trivial. (It also violates ODR by using the internal-linkage None in inline functions, and every single constexpr or FOLLY_CPP14_CONSTEXPR function is ill-formed NDR: you can't implement optional's constexpr API with aligned_storage.) +1 for being co_await-able, but they'd be better off stealing the optional implementation from range-v3 and adding on the rest of their API. – Casey Oct 4 '17 at 15:03

libstdc++ apparently does not implement P0602 "variant and optional should propagate copy/move triviality". You can verify this with:


which fails for libstdc++, and passes for libc++ and the MSVC standard library (which really needs a proper name so we don't have to call it either "The MSVC implementation of the C++ standard library" or "The MSVC STL").

Of course MSVC still won't pass an optional<int> in a register because the MS ABI.

EDIT: This issue has been fixed in the GCC 8 release series.

  • optional still requires a destructor though, and that prevent from returning it in registers. – Maxim Egorushkin Oct 3 '17 at 14:27
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    @MaximEgorushkin it only needs a destructor when T has one. – ratchet freak Oct 3 '17 at 14:52
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    Was that paper adopted? It's not reflected in the latest draft. – Barry Oct 3 '17 at 14:58
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    @Barry Per this it's sitting in Library Evolution right now. – NathanOliver Oct 3 '17 at 15:44
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    Correct, P0602 has not yet been adopted. The author made an attempt to communicate with the major implementors so that optional and vector could be "fixed" before people ship and lock in ABI. I believe libstdc++/libc++/MSFT variant all comply, as do libc++/MSFT optional, but apparently the libstdc++ optional maintainer did not get the memo. – Casey Oct 4 '17 at 14:25

Why does get_std_optional_int() require three mov instructions, while get_my_optional() only needs a single movabs?

The direct cause is that optional is returned through a hidden pointer while pair is returned in a register. Why is that, though? The SysV ABI specification, section 3.2.3 Parameter Passing says:

If a C++ object has either a non-trivial copy constructor or a non-trivial destructor, it is passed by invisible reference.

Sorting out the C++ mess that is optional is not easy, but there seem to be a non-trivial copy constructor at least in the optional_base class of the implementation I checked.

  • 3
    Doesn't have to be, but could be, and that's what counts for the compiler. So you actually have to look at the implementation. – Jester Oct 3 '17 at 13:36

In Calling conventions for different C++ compilers and operating systems by Agner Fog it says that a copy constructor or destructor prevents from returning a structure in registers. This explains why optional is not returned in registers.

There has to be something else preventing the compiler from doing store merging (merges contiguous stores of immediate values narrower than a word into fewer wider stores to reduce the number of instructions)... Update: gcc bug 82434 - -fstore-merging does not work reliably.

  • Any idea what this "something else" might be? – Daniel H Oct 3 '17 at 12:40
  • x86-64 does not have a mov mem, imm64 so you can't merge the stores. – Jester Oct 3 '17 at 12:43
  • @Jester It could load rax with the merged value and store that into [rdi]. – Maxim Egorushkin Oct 3 '17 at 12:46
  • It certainly could, but I don't think that has any inherent speed advantage and this is shorter machine code. It certainly doesn't reduce the number of instructions. – Jester Oct 3 '17 at 13:07
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    @Maxim: gcc7 implemented store coalescing (which gcc3 or gcc4 broke, so gcc for years has sucked at adjacent narrow assignments), but there's still a missed optimization in objects with padding. gcc.gnu.org/bugzilla/show_bug.cgi?id=82142. (clang seems to have the same missed optimization in this case.) gcc and clang will coalesce the stores if your write a function which stores through a pair<int,int> pointer: godbolt.org/g/44zodQ. – Peter Cordes Oct 3 '17 at 17:14

The optimization is technically permitted, even with std::is_trivially_copyable_v<std::optional<int>> being false. However, it may require an unreasonable degree of "cleverness" for the compiler to find. Also, for the specific case of using std::optional as the return type of a function, the optimization may need to be done at link-time rather than compile-time.

Performing this optimization would have no effect on any (well-defined) program's observable behavior,* and is therefore implicitly allowed under the as-if rule. However, for reasons which are explained in other answers, the compiler has not been explicitly made aware of that fact and would need to infer it from scratch. Behavioral static analysis is inherently difficult, so the compiler may not be able to prove that this optimization is safe under all circumstances.

Assuming the compiler can find this optimization, it would then need to alter this function's calling convention (i.e. change how the function returns a given value), which normally needs to be done at link time because the calling convention affects all of the call sites. Alternatively, the compiler could inline the function entirely, which may or may not be possible to do at compile time. These steps would not be necessary with a trivially-copyable object, so in this sense the standard does inhibit and complicate the optimization.

std::is_trivially_copyable_v<std::optional<int>> ought to be true. If it were true, it would be much easier for compilers to discover and perform this optimization. So, to answer your question:

Is this a QoI issue, or is there something in std::optional's specification preventing this optimization?

It's both. The spec makes the optimization substantially harder to find, and the implementation is not "smart" enough to find it under those constraints.

* Assuming you haven't done something really weird, like #define int something_else.

  • 1
    You're including the calling convention as part of "the implementation". That's technically true, but unless you enable whole-program / link-time optimization, it's not something that compilers on a given platform will even try to change other than by fully inlining, or making constant-propagation cloned versions of functions. – Peter Cordes Oct 3 '17 at 17:25
  • I guess gcc could emit something like .gcc_reg_return_get_std_optional_int.clone123 as well as a normal ABI-compliant definition. Callers from other translation units couldn't assume this was present, though, so they'd have to call the regular version (unless you use LTO, in which case it would just inline because it's small). But if the function was actually large, then sure cloning an alternate-calling-convention version of the function would be useful. Probably most useful to return the parts in 2 separate regs, instead of packing into RAX. – Peter Cordes Oct 3 '17 at 17:29
  • @PeterCordes: Are you sure? The implementation of the function seems completely irrelevant here, only the implementation of std::optional should be necessary and since it is a template its implementation is always available. – Matthieu M. Oct 3 '17 at 17:58
  • @MatthieuM.: Yes, I'm confident that gcc and clang are following the C++ ABI they've decided to use, where the criterion for packing into registers if small enough when returning or passing by value is std::is_trivially_copyable_v<foo>. You could maybe change the C++ ABI to implement more complicated rules for the case of template classes where the destructor exists but is known to optimize away, or something. But this might require optimizations to be enabled always for compilers to agree with each other on how to pass certain objects. (e.g. inline and optimize away.) – Peter Cordes Oct 3 '17 at 18:16
  • The C++ ABI is not intended to be stable the way the C ABI / calling convention is (x86-64 System V psABI), but it does have to be possible for different compilers to reliably agree with each other. – Peter Cordes Oct 3 '17 at 18:19

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