Suppose I have a number of statements that I want to execute in a fixed order. I want to use g++ with optimization level 2, so some statements could be reordered. What tools does one have to enforce a certain ordering of statements?

Consider the following example.

using Clock = std::chrono::high_resolution_clock;

auto t1 = Clock::now(); // Statement 1
foo();                  // Statement 2
auto t2 = Clock::now(); // Statement 3

auto elapsedTime = t2 - t1;

In this example it is important that the statements 1-3 are executed in the given order. However, can't the compiler think statement 2 is independent of 1 and 3 and execute the code as follows?

using Clock=std::chrono::high_resolution_clock;

foo();                  // Statement 2
auto t1 = Clock::now(); // Statement 1
auto t2 = Clock::now(); // Statement 3

auto elapsedTime = t2 - t1;
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    If the compiler thinks they're independent when they're not, the compiler is broken and you should use a better compiler. – David Schwartz Jun 13 '16 at 11:43
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    @HowardHinnant: The semantic power of standard C would be improved tremendously if such a directive were defined, and if the aliasing rules were adjusted to exempt reads performed after a barrier of data which was written before it. – supercat Jun 13 '16 at 18:40
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    @LokiAstari Jeremy's answer already showed that effect, but also showed that (predictably) LTO defeats it too. – underscore_d Jun 13 '16 at 18:40
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    @DavidSchwartz In this case it's about measuring the time foo takes to run, which the compiler is allowed to ignore when reordering, just like it's allowed to ignore observation from a different thread. – CodesInChaos Jun 14 '16 at 7:17
up vote 78 down vote accepted
+100

I'd like to try to provide a somewhat more comprehensive answer after this was discussed with the C++ standards committee. In addition to being a member of the C++ committee, I'm also a developer on the LLVM and Clang compilers.

Fundamentally, there is no way to use a barrier or some operation in the sequence to achieve these transformations. The fundamental problem is that the operational semantics of something like an integer addition are totally known to the implementation. It can simulate them, it knows they cannot be observed by correct programs, and is always free to move them around.

We could try to prevent this, but it would have extremely negative results and would ultimately fail.

First, the only way to prevent this in the compiler is to tell it that all of these basic operations are observable. The problem is that this then would preclude the overwhelming majority of compiler optimizations. Inside the compiler, we have essentially no good mechanisms to model that the timing is observable but nothing else. We don't even have a good model of what operations take time. As an example, does converting a 32-bit unsigned integer to a 64-bit unsigned integer take time? It takes zero time on x86-64, but on other architectures it takes non-zero time. There is no generically correct answer here.

But even if we succeed through some heroics at preventing the compiler from reordering these operations, there is no guarantee this will be enough. Consider a valid and conforming way to execute your C++ program on an x86 machine: DynamoRIO. This is a system that dynamically evaluates the machine code of the program. One thing it can do is online optimizations, and it is even capable of speculatively executing the entire range of basic arithmetic instructions outside of the timing. And this behavior isn't unique to dynamic evaluators, the actual x86 CPU will also speculate (a much smaller number of) instructions and reorder them dynamically.

The essential realization is that the fact that arithmetic isn't observable (even at the timing level) is something that permeates the layers of the computer. It is true for the compiler, the runtime, and often even the hardware. Forcing it to be observable would both dramatically constrain the compiler, but it would also dramatically constrain the hardware.

But all of this should not cause you to lose hope. When you want to time the execution of basic mathematical operations, we have well studied techniques that work reliably. Typically these are used when doing micro-benchmarking. I gave a talk about this at CppCon2015: https://youtu.be/nXaxk27zwlk

The techniques shown there are also provided by various micro-benchmark libraries such as Google's: https://github.com/google/benchmark#preventing-optimisation

The key to these techniques is to focus on the data. You make the input to the computation opaque to the optimizer and the result of the computation opaque to the optimizer. Once you've done that, you can time it reliably. Let's look at a realistic version of the example in the original question, but with the definition of foo fully visible to the implementation. I've also extracted a (non-portable) version of DoNotOptimize from the Google Benchmark library which you can find here: https://github.com/google/benchmark/blob/master/include/benchmark/benchmark_api.h#L208

#include <chrono>

template <class T>
__attribute__((always_inline)) inline void DoNotOptimize(const T &value) {
  asm volatile("" : "+m"(const_cast<T &>(value)));
}

// The compiler has full knowledge of the implementation.
static int foo(int x) { return x * 2; }

auto time_foo() {
  using Clock = std::chrono::high_resolution_clock;

  auto input = 42;

  auto t1 = Clock::now();         // Statement 1
  DoNotOptimize(input);
  auto output = foo(input);       // Statement 2
  DoNotOptimize(output);
  auto t2 = Clock::now();         // Statement 3

  return t2 - t1;
}

Here we ensure that the input data and the output data are marked as un-optimizable around the computation foo, and only around those markers are the timings computed. Because you are using data to pincer the computation, it is guaranteed to stay between the two timings and yet the computation itself is allowed to be optimized. The resulting x86-64 assembly generated by a recent build of Clang/LLVM is:

% ./bin/clang++ -std=c++14 -c -S -o - so.cpp -O3
        .text
        .file   "so.cpp"
        .globl  _Z8time_foov
        .p2align        4, 0x90
        .type   _Z8time_foov,@function
_Z8time_foov:                           # @_Z8time_foov
        .cfi_startproc
# BB#0:                                 # %entry
        pushq   %rbx
.Ltmp0:
        .cfi_def_cfa_offset 16
        subq    $16, %rsp
.Ltmp1:
        .cfi_def_cfa_offset 32
.Ltmp2:
        .cfi_offset %rbx, -16
        movl    $42, 8(%rsp)
        callq   _ZNSt6chrono3_V212system_clock3nowEv
        movq    %rax, %rbx
        #APP
        #NO_APP
        movl    8(%rsp), %eax
        addl    %eax, %eax              # This is "foo"!
        movl    %eax, 12(%rsp)
        #APP
        #NO_APP
        callq   _ZNSt6chrono3_V212system_clock3nowEv
        subq    %rbx, %rax
        addq    $16, %rsp
        popq    %rbx
        retq
.Lfunc_end0:
        .size   _Z8time_foov, .Lfunc_end0-_Z8time_foov
        .cfi_endproc


        .ident  "clang version 3.9.0 (trunk 273389) (llvm/trunk 273380)"
        .section        ".note.GNU-stack","",@progbits

Here you can see the compiler optimizing the call to foo(input) down to a single instruction, addl %eax, %eax, but without moving it outside of the timing or eliminating it entirely despite the constant input.

Hope this helps, and the C++ standards committee is looking at the possibility of standardizing APIs similar to DoNotOptimize here.

  • Thank you for your answer. I have marked it as the new best answer. I could have done this earlier, but I have not read this stackoverflow page for many months. I am very interested in using the Clang compiler to make C++ programs. Among other things, I like that one can use Unicode characters in variable names in Clang. I think I will ask more questions about Clang on Stackoverflow. – S2108887 Dec 10 '16 at 9:38
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    While I understand how this prevents foo being optimized away completely, can you elaborate a bit why this prevents the calls to Clock::now() being reordered relative to foo()? Does the optimzer have to assume that DoNotOptimize and Clock::now() have access to and might modify some common global state which in turn would tie them to the in- and output? Or are you relying on some current limitations of the optimizer's implementation? – MikeMB Feb 22 '17 at 11:43
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    DoNotOptimize in this example is a synthetically "observable" event. It is as if it notionally printed visible output to some terminal with the input's representation. Since reading the clock is also observable (you're observing time passing) they cannot be re-ordered without changing the observable behavior of the program. – Chandler Carruth Mar 26 '17 at 2:38
  • I'm still not quite clear with the concept "observable", if the foo function is doing some operations like reading from a socket which may be blocked for a while, does this count a observable operation? And since the read is not a "totally known" operation (right?), will the code keep in order? – reavenisadesk Sep 18 at 8:39

Summary:

There seems to be no guaranteed way to prevent reordering, but as long as link-time/full-program optimisation is not enabled, locating the called function in a separate compilation unit seems a fairly good bet. (At least with GCC, although logic would suggest that this is likely with other compilers too.) This comes at the cost of the function call - inlined code is by definition in the same compilation unit and open to reordering.

Original answer:

GCC reorders the calls under -O2 optimisation:

#include <chrono>
static int foo(int x)    // 'static' or not here doesn't affect ordering.
{
    return x*2;
}
int fred(int x)
{
    auto t1 = std::chrono::high_resolution_clock::now();
    int y = foo(x);
    auto t2 = std::chrono::high_resolution_clock::now();
    return y;
}

GCC 5.3.0:

g++ -S --std=c++11 -O0 fred.cpp :

_ZL3fooi:
        pushq   %rbp
        movq    %rsp, %rbp
        movl    %ecx, 16(%rbp)
        movl    16(%rbp), %eax
        addl    %eax, %eax
        popq    %rbp
        ret
_Z4fredi:
        pushq   %rbp
        movq    %rsp, %rbp
        subq    $64, %rsp
        movl    %ecx, 16(%rbp)
        call    _ZNSt6chrono3_V212system_clock3nowEv
        movq    %rax, -16(%rbp)
        movl    16(%rbp), %ecx
        call    _ZL3fooi
        movl    %eax, -4(%rbp)
        call    _ZNSt6chrono3_V212system_clock3nowEv
        movq    %rax, -32(%rbp)
        movl    -4(%rbp), %eax
        addq    $64, %rsp
        popq    %rbp
        ret

But:

g++ -S --std=c++11 -O2 fred.cpp :

_Z4fredi:
        pushq   %rbx
        subq    $32, %rsp
        movl    %ecx, %ebx
        call    _ZNSt6chrono3_V212system_clock3nowEv
        call    _ZNSt6chrono3_V212system_clock3nowEv
        leal    (%rbx,%rbx), %eax
        addq    $32, %rsp
        popq    %rbx
        ret

Now, with foo() as an extern function:

#include <chrono>
int foo(int x);
int fred(int x)
{
    auto t1 = std::chrono::high_resolution_clock::now();
    int y = foo(x);
    auto t2 = std::chrono::high_resolution_clock::now();
    return y;
}

g++ -S --std=c++11 -O2 fred.cpp :

_Z4fredi:
        pushq   %rbx
        subq    $32, %rsp
        movl    %ecx, %ebx
        call    _ZNSt6chrono3_V212system_clock3nowEv
        movl    %ebx, %ecx
        call    _Z3fooi
        movl    %eax, %ebx
        call    _ZNSt6chrono3_V212system_clock3nowEv
        movl    %ebx, %eax
        addq    $32, %rsp
        popq    %rbx
        ret

BUT, if this is linked with -flto (link-time optimisation):

0000000100401710 <main>:
   100401710:   53                      push   %rbx
   100401711:   48 83 ec 20             sub    $0x20,%rsp
   100401715:   89 cb                   mov    %ecx,%ebx
   100401717:   e8 e4 ff ff ff          callq  100401700 <__main>
   10040171c:   e8 bf f9 ff ff          callq  1004010e0 <_ZNSt6chrono3_V212system_clock3nowEv>
   100401721:   e8 ba f9 ff ff          callq  1004010e0 <_ZNSt6chrono3_V212system_clock3nowEv>
   100401726:   8d 04 1b                lea    (%rbx,%rbx,1),%eax
   100401729:   48 83 c4 20             add    $0x20,%rsp
   10040172d:   5b                      pop    %rbx
   10040172e:   c3                      retq
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    So does MSVC and ICC. Clang is the only one that seems to preserve the original sequence. – Cody Gray Jun 13 '16 at 12:37
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    you don't use t1 and t2 anywhere so it may think the result can be discarded and reorder the code – phuclv Jun 13 '16 at 13:49
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    @Niall - I can't offer anything more concrete, but I think my comment alludes to the underlying reason: The compiler knows that foo() cannot affect now(), nor vice versa, and so does the reordering. Various experiments involving extern scope functions and data seem to confirm this. This includes having static foo() depend on a file-scope variable N - if N is declared as static, reordering occurs, whereas if it's declared non-static (i.e. it's visible to other compilation units, and hence potentially subject to side effects of extern functions such as now()) reordering does not occur. – Jeremy Jun 13 '16 at 13:54
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    @ Lưu Vĩnh Phúc: Except that the calls themselves are not elided. Once again, I suspect this is because the compiler doesn't know what their side effects might be - but it does know that those side effects cannot influence the behaviour of foo(). – Jeremy Jun 13 '16 at 13:57
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    And a final note: specifying -flto (link-time optimisation) causes reordering even in otherwise non-reordered cases. – Jeremy Jun 13 '16 at 14:01

Reordering may be done by the compiler, or by the processor.

Most compilers offer a platform-specific method to prevent reordering of read-write instructions. On gcc, this is

asm volatile("" ::: "memory");

(More information here)

Note that this only indirectly prevents reordering operations, as long as they depend on the reads / writes.

In practice I haven't yet seen a system where the system call in Clock::now() does have the same effect as such a barrier. You could inspect the resulting assembly to be sure.

It is not uncommon, however, that the function under test gets evaluated during compile time. To enforce "realistic" execution, you may need to derive input for foo() from I/O or a volatile read.


Another option would be to disable inlining for foo() - again, this is compiler specific and usually not portable, but would have the same effect.

On gcc, this would be __attribute__ ((noinline))


@Ruslan brings up a fundamental issue: How realistic is this measurement?

Execution time is affected by many factors: one is the actual hardware we are running on, the other is concurrent access to shared resources like cache, memory, disk and CPU cores.

So what we usually do to get comparable timings: make sure they are reproducible with a low error margin. This makes them somewhat artificial.

"hot cache" vs. "cold cache" execution performance can easily differ by an order of magnitude - but in reality, it will be something inbetween ("lukewarm"?)

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    Your hack with asm affects execution time of the statements between timer calls: the code after memory clobber has to reload all variables from memory. – Ruslan Jun 13 '16 at 11:07
  • @Ruslan: Their hack, not mine. There are different levels of purging, and doing something like that is unavoidable for reproducible results. – peterchen Jun 13 '16 at 13:03
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    Note that the hack with 'asm' only helps as a barrier for operations which touch memory, and the OP is interested in more than that. See my answer for more details. – Chandler Carruth Jun 27 '16 at 20:01

The C++ language defines what is observable in a number of ways.

If foo() does nothing observable, then it can be eliminated completely. If foo() only does a computation that stores values in "local" state (be it on the stack or in an object somewhere), and the compiler can prove that no safely-derived pointer can get into the Clock::now() code, then there are no observable consequences to moving the Clock::now() calls.

If foo() interacted with a file or the display, and the compiler cannot prove that Clock::now() does not interact with the file or the display, then reordering cannot be done, because interaction with a file or display is observable behavior.

While you can use compiler-specific hacks to force code not to move around (like inline assembly), another approach is to attempt to outsmart your compiler.

Create a dynamically loaded library. Load it prior to the code in question.

That library exposes one thing:

namespace details {
  void execute( void(*)(void*), void *);
}

and wraps it like this:

template<class F>
void execute( F f ) {
  struct bundle_t {
    F f;
  } bundle = {std::forward<F>(f)};

  auto tmp_f = [](void* ptr)->void {
    auto* pb = static_cast<bundle_t*>(ptr);
    (pb->f)();
  };
  details::execute( tmp_f, &bundle );
}

which packs up a nullary lambda and uses the dynamic library to run it in a context that the compiler cannot understand.

Inside the dynamic library, we do:

void details::execute( void(*f)(void*), void *p) {
  f(p);
}

which is pretty simple.

Now to reorder the calls to execute, it must understand the dynamic library, which it cannot while compiling your test code.

It can still eliminate foo()s with zero side effects, but you win some, you lose some.

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    "another approach is to attempt to outsmart your compiler" If that phrase isn't a sign of having gone down the rabbit hole, I don't know what is. :-) – Cody Gray Jun 13 '16 at 14:54
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    I think it might be helpful to note that the time required for a block of code to execute is not considered an "observable" behavior which compilers are required to maintain. If the time to execute a block of code were "observable", then no forms of performance optimization would be permissible. While it would be helpful for C and C++ to define a "causality barrier" which would require a compiler to hold off on executing any code after the barrier until all side-effects from before the barrier had been handled by the generated code [code which wants to ensure that data has fully... – supercat Jun 13 '16 at 18:12
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    ...propagated through hardware caches would need to use hardware-specific means to do that, but a hardware-specific means of waiting until all posted writes were complete would be useless without a barrier directive to ensure that all pending writes tracked by the compiler must get posted to the hardware before the hardware is asked to ensure that all posted writes are complete.] I know of no way of doing that in either language without using a dummy volatile access or call to outside code. – supercat Jun 13 '16 at 18:15

No it can't. According to the C++ standard [intro.execution]:

14 Every value computation and side effect associated with a full-expression is sequenced before every value computation and side effect associated with the next full-expression to be evaluated.

A full-expression is basically a statement terminated by a semicolon. As you can see the above rule stipulates statements must be executed in order. It is within statements that the compiler is allowed more free rein (i.e. it is under some circumstance allowed to evaluate expressions that make up a statement in orders other than left-to-right or anything else specific).

Note the conditions for the as-if rule to apply are not met here. It is unreasonable to think that any compiler would be able to prove that reordering calls to get the system time would not affect observable program behaviour. If there was a circumstance in which two calls to get the time could be reordered without changing observed behaviour, it would be extremely inefficient to actually produce a compiler that analyses a program with enough understanding to be able to infer this with certainty.

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    There's still the as-if rule though – M.M Jun 13 '16 at 9:58
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    By as-if rule compiler can do anything to code as long as it does not change observable behavior. Time of execution is not observable. So it can reorder arbutrary lines of code as long as result would be same (most compiler do sensible thing and not reorder time calls, but it is not required) – Revolver_Ocelot Jun 13 '16 at 10:00
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    Time of execution is not observable. This is quite strange. From a practical, non-technical point of view, time of execution (a.k.a. "performance") is very observable. – Frédéric Hamidi Jun 13 '16 at 10:06
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    Depends on how you measure time. It is not possible to measure the number of clock cycles taken to execute some body of code in standard C++. – Peter Jun 13 '16 at 10:07
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    @dba You're mixing a few things together. The linker can no longer generate Win16 applications, that's true enough, but that's because they have removed support for generating that type of binary. WIn16 apps don't use the PE format. That doesn't imply that either the compiler or linker has special knowledge about the API functions. The other issue is related to the runtime library. There is absolutely no problem getting the latest version of MSVC to generate a binary that runs on NT 4. I have done it. The problem comes as soon as you try to link in the CRT, which calls functions not available. – Cody Gray Jun 13 '16 at 13:01

No.

Sometimes, by the "as-if" rule, statements may be re-ordered. This is not because they are logically independent of each other, but because that independence allows such a re-ordering to occur without changing the semantics of the program.

Moving a system call that obtains the current time obviously does not satisfy that condition. A compiler that knowingly or unknowingly does so is non-compliant and really silly.

In general, I wouldn't expect any expression that results in a system call to be "second-guessed" by even an aggressively optimizing compiler. It just doesn't know enough about what that system call does.

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    I agree that it would be silly, but I wold not call it non-conformant. Compiler can have knowledge what system call on concrete system exactly does and if it has side effects. I would expect compilers to not reorder such call just to cover common use case, allowing for better user experience, not because standard prohibits it. – Revolver_Ocelot Jun 13 '16 at 10:12
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    @Revolver_Ocelot: Optimisations that change the semantics of the program (okay, save for copy elision) are non-compliant to the standard, whether you agree or not. – Lightness Races in Orbit Jun 13 '16 at 11:31
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    In the trivial case of int x = 0; clock(); x = y*2; clock(); there are no defined ways for the clock() code to interact with the state of x. Under the C++ standard, it doesn't have to know what clock() does -- it could examine the stack (and notice when the computation occurs), but that isn't C++'s problem. – Yakk - Adam Nevraumont Jun 13 '16 at 14:33
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    To take Yakk's point further: it's true that re-ordering the system calls, so that the result of the first is assigned to t2 and the second to t1, would be non-conforming and silly if those values are used, what this answer misses is that a conforming compiler can sometimes re-order other code across a system call. In this case, provided it knows what foo() does (for example because it has inlined it) and hence that (loosely speaking) it's a pure function then it can move it around. – Steve Jessop Jun 13 '16 at 22:38
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    .. again loosely speaking, this is because there's no guarantee that the actual implementation (albeit not the abstract machine) won't speculatively calculate y*y before the system call, just for fun. There is also no guarantee that the actual implementation won't use the result of this speculative calculation later at whatever point x is used, therefore doing nothing between the calls to clock(). The same goes for whatever an inlined function foo does, provided it has no side-effects and cannot depend on state that might be altered by clock(). – Steve Jessop Jun 13 '16 at 22:45

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