This sentence:
Since GCC totally ignores inline specifiers, it's a little difficult
for me to know when a function has been marked inline by me or not.
is an incorrect basis to start with. (And of course, we can replace GCC with any other modern compiler for this discussion).
Sure, the compiler may ignore the inline
keyword for the purposes of deciding whether the function is inlined or not - and it CERTAINLY can inline functions that are NOT marked inline. The compiler does, however, use the inline
keyword [and it's equivalence of "body declared inside the struct"] when generating the final output, to avoid multiple definitions of a function that has code generated multiple times in different compile units. For example:
foo.h:
inline int foo() { return 42; }
a.cpp:
#include "foo.h"
...
b.cpp:
#include "foo.h"
...
If the function foo
was not declared inline
, the linker would complain about multiple definitions of the function foo
if we link the results of a.cpp and b.cpp into one executable file.
However, you are right in that the compiler will not decide to inline functions on the basis of the inline
keyword, but based on other aspects, such as how many times the function is called, whether the source of the function is "visible" to the compiler, etc.
As a simple rule:
- Compiler will not inline functions that it hasn't got the source code for.
- Compiler will not inline virtual functions (unless it can determine the type of the object the virtual function belongs to)
- The compiler will inline functions that are small and/or only called once, particularly if the function is static.
Since inlining happens towards the end of compilation (when ALL the source code have been parsed and placed in some sort of AST (Abstract Syntax Tree) or similar form), whether the function is before or after the point of usage typically doesn't really matter - of course, if the call is to a function that isn't part of the AST (the source code is not available), the compiler has no choice but to NOT inline it.
The exception to "can't inline when the source isn't available" is so called LTO "Link Time Optimisation". A traditional linker will just take a collection of machine code instructions and paste them together in whatever order they are listed, without any knowledge of what a function is [simplified view, sufficient for this discussion] and then fix up any addresses for functions and variable that the compiler couldn't resolve directly. In contrast, LTO stores the "object files" as an intermediate representation, and the final machine code generation is done by the linker phase. This means that the linker has enough information to for example move code around to inline the code in one function into another. This technology is available in recent releases of for example gcc (4.9.0 has LTO as a full feature, earlier versions had a bit less support)
inline
very literally as a command to inline calls.