7

I was solving an exercise online, and at one point i needed to delete the "" from a the beginning and end of a string. This was my code:

void static inline process_value(std::string &value) {
    if (value.back() !='>') {
        value = value.substr(1, value.size()-2);
    }
}

Called from this benchmark loop:

static void UsingStatic(benchmark::State& state) {
  // Code inside this loop is measured repeatedly
  for (auto _ : state) {
      std::string valor("\"Hola\"");
      process_valueS(valor);
    // Make sure the variable is not optimized away by compiler
    benchmark::DoNotOptimize(valor);
  }
}

Just because of curiosity I did a benchmark.

  • Compiler: Clang-9.0
  • std: c++20
  • optim: O3
  • STL: libstdc++(GNU)

While I was at it I decided to remove static from process_value, making void inline process_value that was otherwise the same. To my surprise it was slower.

I thought that static only meant that the function was just for a file. But here it says that " 'static' means that the function should be inlined by the compiler if possible". But in that case when i removed static I think that the result should not have changed. Now I'm am confused, what other things does static do other than delimiting the function to a single .cpp, how does that affect performance?

The disassembly on QuickBench shows that the NoUsingStatic loop actually calls process_value instead of inlining it, despite the inline keyword making it legal for the compiler to do so. But UsingStatic does inline the call to process_valueS. That difference in compiler decision-making presumably explains the difference in performance, but why would clang choose not to inline a simple function declared void inline process_value(std::string &value){ ... }?


EDIT: Beacuse the question was closed because it was not clear enough, i deleted parts that where not related to the question. But if im missing some information please tell me in the comments

11
  • 1
    static and inlining are not directly related. May 25, 2020 at 15:43
  • inlining also has nothing to do with this. The information you read was wrong.
    – john
    May 25, 2020 at 15:50
  • @rustyx: I think the question can simply be re-opened, especially after my edit. I looked at the asm on quickbench so I was able to edit the question from just asking about a perf difference to asking about specifically why clang chose not to inline without the static keyword. May 25, 2020 at 20:32
  • @rustyx: In the current QuickBench link, I see callq 2102b0 <process_value... in the NoUsingStatic tab. That's not just an allocator. I think the asm around the call is just creating a std::string object on the stack and passing its address. May 25, 2020 at 20:55
  • 2
    @john: static does actually affect clang's decision to inline or not here. Perhaps with a non-tiny function, it thinks there will probably be callers in other compilation units so there's a tradeoff with total code size. With static / static inline there's literally nothing to lose when inlining into the only call-site in this translation unit; other TUs couldn't call a non-inline definition so there's zero possible benefit to emitting one instead of inlining. May 25, 2020 at 21:22

2 Answers 2

6
+50

Clang uses a cost based decision whether a function will be inlined or not. This cost is affected by a lot of things. It is affected by static.

Fortunately, clang has an output, where we can observe this. Check out this godbolt link:

void call();

inline void a() {
    call();
}

static inline void b() {
    call();
}

void foo() {
    a();
    b();
}

In this little example, a() and b() are the same, the only exception is that b() is static.

If you move the mouse over the calls a() or b() on godbolt (in OptViewer window), you can read:

a(): cost=0, threshold=487

b(): cost=-15000, threshold=487

(clang will inline a call, if the cost is less than the threshold.)

clang gave b() a much lower cost, because it is static. It seems that clang will only give this -15000 cost reduction for a static function only once. If b() is called several times, the cost of all b()s will be zero, except one.

Here are the numbers for your case, link:

process_value(): cost=400, threshold=325 -> it is just above the threshold, won't be inlined

process_valueS():: cost=-14600, threshold=325 -> OK to inline

So, apparently, static can have a lot of impact, if it is only called once. Which makes sense, because inlining a static function once doesn't increase code size.

Tip: if you want to force clang to inline a function, use __attribute__((always_inline)) on it.

0

inline is just an advise to the compiler, which may or may not really inline that your particular code.

Regarding to the static keyword, if it's applied to a global variable, then it has the file-scope (as you've mentioned) if you compile your code as a separate compilation-unit. So it's even possible to have your static global variables accessible from other files if you compile them as a single compilation unit. This means that in reality, the scope of the global static variables is not the file but the compilation unit (which may or may not be one single file).

But, since you have a global static function, not a variable, it is accessible from everywhere as a global static function.

EDIT: As suggested by @Peter Cordes in comments below, it may be a real mess with inline and static at the same time, so the official doc ( https://en.cppreference.com/w/cpp/language/inline ) says that the redefinition of inline functions (and variables since C++17) must be non-static.

3
  • inline is just an advise to the compiler - not just advice: it also makes it legal to define the function in multiple translation units. (And in fact promises that every TU that calls the function at all will see a definition of it). So it makes it legal for the compiler to not emit a stand-alone definition of the function in TUs where every call site decided to inline the function. But if the compiler chooses not to inline the function, all TUs will call the same shared definition of it. (So it's UB if different TUs have conflicting definitions, IIRC). May 31, 2020 at 23:52
  • Like for variables, static still means that every translation unit has its own private version of the function, which might or might not be defined the same way in other translation units, even though it has the same name. Link-time identical-code-folding optimization could still collapse those separate definitions back into one, but clang's inlining heuristics are designed for code that uses static correctly, for single-TU functions. (Using #include to create one translation unit out of multiple source files is possible, yes, that's why we have the term "translation unit".) May 31, 2020 at 23:57
  • @PeterCordes: thanks for the comments, didn't know that it may be a real mess with inline and static at the same time, so I ended up reading the official doc: en.cppreference.com/w/cpp/language/inline#Description which states that the redefinition of inline functions (and variables since C++17) must be non-static.
    – Hack06
    Jun 1, 2020 at 9:48

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