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I am curious about the liberties that a compiler has when optimizing. Let's limit this question to GCC and C/C++ (any version, any flavour of standard):

Is it possible to write code which behaves differently depending on which optimization level it was compiled with?

The example I have in mind is printing different bits of text in various constructors in C++ and getting a difference depending on whether copies are elided (though I've not been able to make such a thing work).

Counting clock cycles is not permitted. If you have an example for a non-GCC compiler, I'd be curious, too, but I can't check it. Bonus points for an example in C. :-)

Edit: The example code should be standard compliant and not contain undefined behaviour from the outset.

Edit 2: Got some great answers already! Let me up the stakes a bit: The code must constitute a well-formed program and be standards-compliant, and it must compile to correct, deterministic programs in every optimization level. (That excludes things like race-conditions in ill-formed multithreaded code.) Also I appreciate that floating point rounding may be affected, but let's discount that.

I just hit 800 reputation, so I think I shall blow 50 reputation as bounty on the first complete example to conform to (the spirit) of those conditions; 25 if it involves abusing strict aliasing. (Subject to someone showing me how to send bounty to someone else.)

share|improve this question
Realize that, in the case of copy elision, the compiler is specifically allowed to change the observable behavior of the program. – Robᵩ Jun 15 '11 at 21:14
@Rob: That's fine, I'd be very happy to see just a working example of that. I understand that all constructors are expected to yield semantically identical objects, so by putting print routines in them I'm purposefully introducing a discrimination that the compiler doesn't have to be concerned by. That would be an acceptable example, though! – Kerrek SB Jun 15 '11 at 21:17
"I've not been able to make such a thing work" - maybe in GCC copy ctor elision is enabled even with no optimization? – Steve Jessop Jun 15 '11 at 21:18 - notice how Func1 doesn't invoke the copy constructor, but Func2 does. – Robᵩ Jun 15 '11 at 21:31
@Kerrek: aha! man to the rescue, yes you can, with -fno-elide-constructors. Assuming that you permit such a fine-grained option as a "different optimization level", I think that fits your requirements. – Steve Jessop Jun 15 '11 at 21:43

10 Answers 10

up vote 16 down vote accepted

The portion of the C++ standard that applies is §1.9 "Program execution". It reads, in part:

conforming implementations are required to emulate (only) the observable behavior of the abstract machine as explained below. ...

A conforming implementation executing a well-formed program shall produce the same observable behavior as one of the possible execution sequences of the corresponding instance of the abstract machine with the same program and the same input. ...

The observable behavior of the abstract machine is its sequence of reads and writes to volatile data and calls to library I/O functions. ...

So, yes, code may behave differently at different optimization levels, but (assuming that all levels produce a conforming compiler), but they cannot behave observably differently.

EDIT: Allow me to correct my conclusion: Yes, code may behave differently at different optimization levels as long as each behavior is observably identical to one of the behaviors of the standard's abstract machine.

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How does this square with the invocation of different constructors? If I write T x /* default */; x = T(2, 3);, would it be illegal to optimize this to T x(2, 3);? – Kerrek SB Jun 15 '11 at 21:32
Note "one of the possible execution sequences". It doesn't have to be the same one at each optimization level. So for example the compiler is allowed to evaluate function arguments in one order at -O0 and a different order at -O4. A program whose output differs according to which order actually occurs is valid, although it isn't what the C standard calls "a strictly conforming program". Then again printf("%d\n", CHAR_BIT) isn't a strictly conforming program either since the output is implementation-defined. – Steve Jessop Jun 15 '11 at 21:35
@Kerrek: that optimization is illegal for example if the assignment operator T::operator=(const T &) has observable side-effects. As you know there's a special rule to allow copy ctor elision even when the copy ctor has side-effects. There's no such rule for copy assignment. Same applies to the default construction, its observable behavior can't be elided either. But as long as nothing affects observable behavior, the compiler can leave out anything it wants (and if x is unused, construct no object at all). – Steve Jessop Jun 15 '11 at 21:36
@Steve: I didn't actually know about the exception for the copyctor. Does that mean that the indeterminacy in how often something gets copied (or default-constructed) is the only thing that may affect visible behaviour according to the standard? – Kerrek SB Jun 15 '11 at 21:46
@Kerrek: you did know, even if you didn't know that it was an explicit special case, since you mentioned copy ctor elision in the question :-). It's not the only thing: anything that is unspecified or implementation-defined can change. The language used is 12.8/15 is "the implementation is allowed to do this", but in effect what it's saying is the same as if it said "it is unspecified whether the implementation does this" – Steve Jessop Jun 15 '11 at 21:51

Is it possible to write code which behaves differently depending on which optimization level it was compiled with?

Only if you trigger a compiler's bug.


This example behaves differently on gcc 4.5.2:

void foo(int i) {

main() {

Compiled with -O0 creates a program crashing with a segmentation fault.
Compiled with -O2 creates a program entering an endless loop.

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or in the code, of course. – Christian Rau Jun 15 '11 at 21:07
Your example is not a compiler bug though, it works fine with optimization because gcc does tail call optimization, it crashes without optimization because you run out of stack space. – nos Jun 15 '11 at 21:19
@nos: At no point does the OP state that he is looking for compiler bugs. – Dennis Zickefoose Jun 15 '11 at 21:25
The above is definitely not a compiler bug. It sounds like the code is working perfectly in both cases. – Loki Astari Jun 15 '11 at 22:34
Not only if you trigger a bug. An example: int x = printf("hello") + printf("world"); It could print helloworld or worldhello, and which it does might depend on whether optimization is turned on. I.e. optimization could change things where the behavior is unspecified. – R.. Jun 16 '11 at 2:10

Floating point calculations are a ripe source for differences. Depending on how the individual operations are ordered, you can get more/less rounding errors.

Less than safe multi-threaded code can also have different results depending on how memory accesses are optimized, but that's essentially a bug in your code anyhow.

And as you mentioned, side effects in copy constructors can vanish when optimization levels change.

share|improve this answer
I'd like to exclude multithreading stuff like that because that's essentially just undefined behaviour -- you're only allowed a multithreading example if it synchronizes properly. I hadn't thought about floating point inaccuracies, let's discount those, too (though that's a fair point). – Kerrek SB Jun 15 '11 at 21:20

For C, almost all operations are strictly defined in the abstract machine and optimizations are only allowed if the observable result is exactly that of that abstract machine. Exceptions of that rule that come to mind:

  • undefined behavior don't has to be consistent between different compiler runs or executions of the faulty code
  • floating point operations may cause different rounding
  • arguments to function calls can be evaluated in any order
  • expressions with volatile qualified type may or may not be evaluated just for their side effects
  • identical const qualified compound literals may or may be not folded into one static memory location
share|improve this answer

OK, my flagrant play for the bounty, by providing a concrete example. I'll put together the bits from other people's answers and my comments.

For the purpose of different behaviour at different optimizations levels, "optimization level A" shall denote gcc -O0 (I'm using version 4.3.4, but it doesn't matter much, I think any even vaguely recent version will show the difference I'm after), and "optimization level B" shall denote gcc -O0 -fno-elide-constructors.

Code is simple:

#include <iostream>

struct Foo {
    ~Foo() { std::cout << "~Foo\n"; }

int main() {
    Foo f = Foo();

Output at optimization level A:


Output at optimization level B:


The code is totally legal, but the output is implementation-dependent because of copy constructor elision, and in particular it's sensitive to gcc's optimization flag that disables copy ctor elision.

Note that generally speaking, "optimization" refers to compiler transformations that can alter behavior that is undefined, unspecified or implementation-defined, but not behavior that is defined by the standard. So any example that satisfies your criteria necessarily is a program whose output is either unspecified or implementation-defined. In this case it's unspecified by the standard whether copy ctors are elided, I just happen to be lucky that GCC reliably elides them pretty much whenever allowed, but has an option to disable that.

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Nooo, wait, I really want to give the bounty to Rob, I just had to wait 24hrs with it, and I feel bad for not having done it back when I first asked the question... is that OK? I can give you bounty on some other question if you like! Copy-constructor elision is definitely one of the most interesting aspects of optimization, and that GCC option is a cool find. I would happily split the bounty if that's an option... – Kerrek SB Aug 17 '11 at 18:48
Hmm, you've certainly made most of the constructive comments to this question, so you definitely deserve the moral bounty. Quite a dilemma, I wish there were a way to pay tribute rep points that are not limited to one user per question. – Kerrek SB Aug 17 '11 at 18:50
@Kerrek: no worries, I'm sure you've upvoted plenty of my answers elsewhere and given me rep that way, we both hang around the C++ questions enough. Sorry, I didn't realise that you created the bounty because you had in mind to award it to Rob's answer. I just spotted the question under the "featured" tab and recognized it, so I knew I could give a bounty-hunting answer without effort. I totally don't "deserve" a bounty just for bothering to type out the code and run it to confirm the result I expected, on most questions I do that for normal upvotes :-) – Steve Jessop Aug 17 '11 at 18:53
Cool, and I'm sure we'll come up with another opportunity before long :-) (I think I still have one unanswered question out, for that matter.) – Kerrek SB Aug 17 '11 at 18:57
You do have an unanswered question, but I don't know the answer so that's no use. This is why I don't win bounties, I do enough hard work on my job without going beyond the low-hanging fruit and into real research and testing to answer SO questions ;-) – Steve Jessop Aug 17 '11 at 19:06

Anything that is Undefined Behavior according to the standard can change its behavior depending on optimization level (or moon-phase, for that matter).

share|improve this answer
Yes, true. Do let us exclude anything undefined. I would like a well-defined, standard-conforming program which compiles correctly in all optimization levels and gives correct, deterministic programs but which behave differently. – Kerrek SB Jun 15 '11 at 21:24
@Kerrek SB: How about unspecified behavior? Given a function call like f(a(x), b(y)), we know that a(x) is evaluated either before or after b(y), but not concurrently. – David Thornley Jun 15 '11 at 21:35
@David: Ah, evaluation order, I see. Hm... is that affectable by optimisation? I'd say let's discount it because it's already non-deterministic within the standard, but if you have a working example, let's see it. – Kerrek SB Jun 15 '11 at 22:05
@Kerrek: the standard doesn't say anything about optimization levels or what they mean. The only room for code to behave differently at different optimization levels, is for the implementation to make different decisions about things that the standard doesn't wholly pin down. So any example, including the copy elision one, is bound to be an example of something that's either implementation-defined, unspecified, or undefined behavior. – Steve Jessop Jun 16 '11 at 1:40

The -fstrict-aliasing option can easily cause changes in behavior if you have two pointers to the same block of memory. This is supposed to be invalid but is actually quite common.

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Yeah, I figured that... did that ever happen to you in reality, though? – Kerrek SB Jun 15 '11 at 21:19
@Kerrek: it shouldn't be too hard to come up with an example, I think I've managed it before. Start with float f = 0; int &a = *(int*)(&f); int b = a; f = 1; int c = a; std::cout << a << " " << b << " " << c << "\n";, then play around with it until you can get the compiler to order the operations differently at different optimization levels, and/or entirely omit one or both assignments to f at some levels but not others. The optimizer is entitled to assume that f = 1; doesn't alter the referand of a, so you just need to catch it doing so. – Steve Jessop Jun 15 '11 at 21:22
@Kerrek, sorry I don't remember a specific instance. And if I did run into it, it probably wasn't with gcc. There's gotta be a reason it sticks with me though. – Mark Ransom Jun 15 '11 at 21:40
@Steve: Interesting. No luck with that yet, but I'll try and tweak the values. – Kerrek SB Jun 15 '11 at 21:44

Since copy constructor calls can be optimized away, even if they have side effects, having copy constructors with side-effects will cause unoptimized and optimized code to behave differently.

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Yeah, that was my idea to begin with, it's just that I never managed to actually get different behaviour by varying the optimization level. Steve Jessop discovered -fno-elide-constructors though, which does the trick. – Kerrek SB Jun 15 '11 at 22:04

This C program invokes undefined behavior, but does display different results in different optimization levels:

#include <stdio.h>
$ for i in 0 1 2 3 4 
    do echo -n "$i: " && gcc -O$i x.c && ./a.out 
0: 5
1: 5
2: 5
3: -1
4: -1

void f(int a) {
  int b;
  printf("%d\n", (int)(&a-&b));
int main() {
 return 0;
share|improve this answer
If you invoke undefined behaviour, I would say the natural thing is to expect different outcomes. Note that the difference in the output does not have to be even due to the optimization level. By invoking undefined behaviour, each run of the program is allowed to produce a different output. – Schedler Jun 17 '11 at 16:44
Granted, and worth mentioning. But so far no one has produced an example that varies according to optimization level and doesn't require UB. – Robᵩ Jun 17 '11 at 16:47
So the idea here is to print addresses of variables? Interesting, that's certainly something that can vary... hadn't thought of that. Cheers. – Kerrek SB Jun 17 '11 at 17:32
@Kerrek - No, the idea is to print the difference of addresses of varables. Specifically, it measures whether the function had a frame pointer, or perhaps was inlined. – Robᵩ Jun 17 '11 at 19:23
+1 for this one. Although formally it's undefined behavior and not allowed under the stricter version of the question, in practice most implementations do pretty much define the results of pointer arithmetic on objects that aren't both subobjects of some common object. So that's almost, but not quite, implementation-defined, and then the actual relative position of a and b is unspecified. Anyway, it's a fairly ingenious answer that on pretty much any implementation isn't UB for that implementation, even though it's UB for the standard. – Steve Jessop Aug 17 '11 at 19:02

Got some interesting example in my OS course today. We analized some software mutex that could be damaged on optimization because the compiler does not know about the parallel execution.

The compiler can reorder statements that do not operate on dependent data. As I already statet in parallelized code this dependencie is hidden for the compiler so it could break. The example I gave would lead to some hard times in debugging as the threadsafety is broken and your code behaves unpredictable because of OS-scheduling issues and concurrent access errors.

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Was it a bug or was it expected behaviour in light of the optimization steps? – Kerrek SB Jun 15 '11 at 21:11
It is definitely a bug as the mutex does not work any longer. But it is not the compilers fault though as it is not designed to recognize parallel access. Its the programmers responsibility to mark this for the compiler with the keyword volatile. Seen as such I would not call it bug anymore. – Nobody Jun 15 '11 at 21:15
volatile isn't enough. C++0x and C1x introduce atomic types because of that. – ninjalj Jun 15 '11 at 21:44
good to know but are they implemented yet? – Nobody Jun 16 '11 at 7:18

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