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I am wondering whether there is any difference between inlining functions on a linker level or compiler level in terms of execution speed?

e.g. if I have all my functions in .cpp files and rely on the linker to do inlining, will this inlining potentially be less efficient than say defining some functions in the headers for selected inlining on the compiler level or unity builds without any linking and all inlining done by the compiler?

If the linker is just as efficient, why would one then still bother inlining functions explicitly on the compiler level? Is that just for convenience, say there is just a one line constructor hence one can't be bothered with a .cpp file?

I suppose this might depend on the compiler, in which case I would be most interested in Visual C++ (Windows) and gcc (Linux).


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Which linker do you use that does inlining? – nbt May 10 '11 at 10:38
@unapersson: Visual C++ has so-called link-time code generation that seems to be able to do just about anything while emitting code. – sharptooth May 10 '11 at 10:40
The linker is collecting all the modules and then calls up the compiler again to finish the code generation. That allows inlining between .cpp files, among other things. – Bo Persson May 10 '11 at 11:08
Linkers don't inline code, they don't know how to delete machine code produced by the compiler. /LTCG serves a very different purpose, it adds code to provide instrumentation data to optimize the executable image layout. That code is temporary. – Hans Passant May 10 '11 at 12:57
@Hans Passant: msdn.microsoft.com/en-us/library/xbf3tbeh(v=vs.80).aspx says that among other things does: Cross-module inlining. At any rate, there are other linkers that do it, so stating that Linkers don't inline code is an overstatement (in case you want to consider that in the previous case, the linker does not really optimize but rather calls the compiler to optimize). – David Rodríguez - dribeas May 10 '11 at 13:25
up vote 3 down vote accepted

The general rule is all else being equal the closer to execution (compiling->linking->(maybe JIT)->execution) the optimization is done the more data the optimizer has and the better optimization it can perform. So unless the optimizer is dumb you should expect better results when inlining is done by the linker - the linker will know more about the invokation context and do better optimization.

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Good answer … but as I understood it, the question is precisely whether all other things are equal. – Konrad Rudolph May 10 '11 at 10:36
@Konrad Rudolph: Well, true. And also the toolchain can be buggy, so one has to test it on his toolchain to be sure. – sharptooth May 10 '11 at 10:38
I definitely don't agree with this. Static compilers and linkers have vastly more time in which to do their work than JIT or dynamic optimization, which makes the scope of their efforts much larger. – Puppy May 10 '11 at 10:43
@DeadMG: That would cancel "all else being equal", won't it? – sharptooth May 10 '11 at 10:54
I am not sure that this hierarchy actually holds... Consider a variable that is only used as argument to a function, and that the actual implementation of the function completely ignores: int x = complex_calculation(); foo( x );, and void foo(int x) { std::cout << "Hi!"; }. The compiler cannot possibly know whether x is used inside foo (unless it can inline it itself), and that means that it will create the variable and it will call complex_calculation. Even if the linker inlines foo, I don't think that the linker can actually remove those costs after the fact. – David Rodríguez - dribeas May 10 '11 at 11:12

Generally, by the time the linker is run, your source has already been compiled into machine code. The linkers job is to take all the code fragments and link then together (possibly fixing addresses along the way). In such a case, there is no room for performing inlining.

But all is not lost. Gcc does provide a mechanism for link time optimization (using the -flto) option when compiling and linking. This causes gcc to produce a byte code that can then be compiled and linked by the linker into a single executable. Since the byte code contains more information than optimized machine code. The linker can now perform radical optimization on the whole codebase. Something that the compiler cannot do.

See here for more details on gcc. Not to sure about VC++ though.

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The relevant links for VC++ are /LTCG and /GL. – ildjarn May 10 '11 at 11:15
Cheers thanks good links – Cookie May 10 '11 at 14:54

Inlining is normally performed within a single translation unit (.cpp file). When you call functions in another file, they’re never inlined.

Link Time Optimization (LTO) changes this, allowing inlining to work across translation units. It should always be equal or better (sometimes very very significantly) to regular linking in terms of how efficient the generated code is.

The reason both options are still available is that LTO can take a large amount of RAM and CPU – I’ve had VC++ take several minutes on linking a large C++ project before. Sometimes it’s not worth it to enable until you ship. You could also run out of address space with a large enough project, as it has to load all that bytecode into RAM.

For writing efficient code, nothing changes – all the same rules apply with LTO. It is potentially more efficient to explicitly define an inline function in a header file versus depending on LTO to inline it. The inline keyword only provides a hint so there’s no guarantee, but it might nudge it into being inlined where normally (with or without LTO) it wouldn’t be.

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(review) Well phrased answer for a first answer. Introduce LTO with its full-name the first time you use it, especially since the question didn't define LTO, if your answer is accepted people will probably read it right after the question. – Hassan Syed May 10 '11 at 12:23
Thanks for the tip! I'll remember that next time I answer. LTO is of course Link Time Optimization. – Cory Nelson May 10 '11 at 12:40
Sorry I am a bit confused. On the one hand you say LTO is as least as efficient as explicit inlining, on the other hand you say explicit inlining might nudge it to being inlined (and hence I assume potentially more efficient) when LTO wouldn't inline it? – Cookie May 10 '11 at 12:49
LTO is at least as efficient as "regular linking" (non-LTO). LTO or not, explicit inlining is potentially more efficient than letting the compiler choose what to inline. – Cory Nelson May 10 '11 at 13:04
So does that mean that in terms of optimization and final execution speed one should try to inline rather more than less? E.g. for small classes (e.g. below 50 lines of code), write everything in the class definition of the header file? If one has a lot of those headers included in multiple cpp files, does this additional size of each compilation unit get reduced again by the linker? – Cookie May 10 '11 at 13:59

If the function is inlined, there would be no difference.

I believe the main reason for having inline functions defined in the headers is history. Another is portability. Until resently most compilers did not do link time code generation, so it having the functions in the headers was a necessity. That of course affects code bases started on more than a couple of years ago.

Also, if you still target some compilers that don't support link time code generation, you dont have a choice.

As an aside, I have in one case been forced to add a pragma to ask one specific compiler not to inline an init() function defined in one .cpp file, but potentially called from many places.

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