I noticed that Google's C++ style guide cautions against inlining functions with loops or switch statements:

Another useful rule of thumb: it's typically not cost effective to inline functions with loops or switch statements (unless, in the common case, the loop or switch statement is never executed).

Other comments on StackOverflow have reiterated this sentiment.

Why are functions with loops or switch statements (or gotos) not suitable for or compatible with inlining. Does this apply to functions that contain any type of jump? Does it apply to functions with if statements? Also (and this might be somewhat unrelated), why is inlining functions that return a value discouraged?

I am particularly interested in this question because I am working with a segment of performance-sensitive code. I noticed that after inlining a function that contains a series of if statements, performance degrades pretty significantly. I'm using GNU Make 3.81, if that's relevant.

  • 4
    I'd recommend leaving inlining decisions to the compiler - and so do compiler-writers, who happily ignore which functions the programmer declared inline. – EOF Mar 24 '15 at 1:21
  • 6
    "I'm using GNU Make 3.81, if that's relevant." The more relevant portion might be the C++ compiler implementation used. – πάντα ῥεῖ Mar 24 '15 at 1:21
  • Inline is generally within 5 lines of code optimization, cycle and switch statements usually have a large number of logic. And if you need to optimize, the rule of 80/20, find out the pathogeny, careful optimization. Everything after optimization, considering inline – Ron Tang Mar 24 '15 at 1:23
  • I usually don't use inline without checking asm. – user3528438 Mar 24 '15 at 1:25
  • I've inspected a significant sample of our code as instruction dumps in kdb, and from my experience, our compiler is actually inlining functions that are labelled inline, and explicitly calling functions that are not inline. For my case I think I can assume that this process is relatively straightforward. – olliezhu Mar 24 '15 at 1:32

Inlining functions with conditional branches makes it more difficult for the CPU to accurately predict the branch statements, since each instance of the branch is independent.

If there are several branch statements, successful branch prediction saves a lot more cycles than the cost of calling the function.

Similar logic applies to unrolling loops with switch statements.

The Google guide referenced doesn't mention anything about functions returning values, so I'm assuming that reference is elsewhere, and requires a different question with an explicit citation.

  • Yes, the reference to functions returning values was just something I was seeing around StackOverflow on the topic of inline functions, often in the same breath as the warnings against inlining functions with loops and switch statements. – olliezhu Mar 24 '15 at 1:27
  • 3
    @uhwuggawuh: The reference you gave for that is a 0-point answer by a 1-reputation author... – EOF Mar 24 '15 at 1:29
  • 1
    @uhwuggawuh: No. I'm saying that not inlining will make it more likely that the CPU will correctly predict branches, making the loops and other branches significantly faster. – rici Mar 24 '15 at 1:42
  • 1
    @rici: unless calling the same function in different places with very different arguments ends up confusing the branch predictor... – EOF Mar 24 '15 at 1:43
  • 1
    @uhwuggawuh: Most branch predictors build up a history of past branches, and use the virtual address of the branch to find its history. If you unroll a loop containing switch then you duplicate all the branches in the switch, making the CPU take longer to get good branch history and also consuming more of the CPU's (limited number of) "branch prediction slots". – Brendan Mar 24 '15 at 2:56

While in your case, the performance degradation seems to be caused by branch mispredictions, I don't think that's the reason why the Google style guide advocates against inline functions containing loops or switch statements. There are use cases where the branch predictor can benefit from inlining.

A loop is often executed hundreds of times, so the execution time of the loop is much larger than the time saved by inlining. So the performance benefit is negligible (see Amdahl's law). OTOH, inlining functions results in increase of code size which has negative effects on the instruction cache.

In the case of switch statements, I can only guess. The rationale might be that jump tables can be rather large, wasting much more memory in the code segment than is obvious.

I think the keyword here is cost effective. Functions that cost a lot of cycles or memory are typically not worth inlining.


The purpose of a coding style guide is to tell you that if you are reading it you are unlikely to have added an optimisation to a real compiler, even less likely to have added a useful optimisation (measured by other people on realistic programs over a range of CPUs), therefore quite unlikely to be able to out-guess the guys who did. At least, do not mislead them, for example, by putting the volatile keyword in front of all your variables.

Inlining decisions in a compiler have very little to do with 'Making a Simple Branch Predictor Happy'. Or less confused.

First off, the target CPU may not even have branch prediction.

Second, a concrete example:

Imagine a compiler which has no other optimisation (turned on) except inlining. Then the only positive effect of inlining a function is that bookkeeping related to function calls (saving registers, setting up locals, saving the return address, and jumping to and back) are eliminated. The cost is duplicating code at every single location where the function is called.

In a real compiler dozens of other simple optimisations are done and the hope of inlining decisions is that those optimisations will interact (or cascade) nicely. Here is a very simple example:

int f(int s)
 switch (s) {
   case 1: ...; break;
   case 2: ...; break;
   case 42: ...; return ...;
 return ...;

void g(...)
  int x=f(42);

When the compiler decides to inline f, it replaces the RHS of the assignment with the body of f. It substitutes the actual parameter 42 for the formal parameter s and suddenly it finds that the switch is on a constant value...so it drops all the other branches and hopefully the known value will allow further simplifications (ie they cascade).

If you are really lucky all calls to the function will be inlined (and unless f is visible outside) the original f will completely disappear from your code. So your compiler eliminated all the bookkeeping and made your code smaller at compile time. And made the code more local at runtime.

If you are unlucky, the code size grows, locality at runtime decreases and your code runs slower.

It is trickier to give a nice example when it is beneficial to inline loops because one has to assume other optimisations and the interactions between them.

The point is that it is hellishly difficult to predict what happens to a chunk of code even if you know all the ways the compiler is allowed to change it. I can't remember who said it but one should not be able to recognise the executable code produced by an optimising compiler.

  • I wish there were a standard-defined way to have code specify that a certain algorithm should be used if it could be in-lined with certain values as constants and a different algorithm used in other cases. For example, code to bit-reverse a 32-bit value could be implemented as a combination of masks and shifts, a loop, or a call to an optimized piece of machine-code. If the value to be reversed is a constant, the combination of masks and shifts would compile down to a constant, but using the masks and shifts on a variable would yield a bloated mess which may be slower than a loop. – supercat Jul 25 '15 at 20:45
  • Some compilers might be able to recognize that a loop written in C, given a constant input, would yield a constant output, but many would not. The machine code could be twice as fast as what a typical compiler could produce, but even when the input is constant no compiler would likely figure out that the output was constant as well. – supercat Jul 25 '15 at 20:48
  • I know where you are going with this :). I think, if you are very keen, you can get the 32-bit reverse example to compile to different algorithms (and then to constants) by using the tempo partial evaluator (phoenix.inria.fr/software/past-projects/tempo). It is ancient but you will make a lot of old people happy. – user1666959 Jul 26 '15 at 19:38

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.