inline inserts the code at the call site, saving on creation of stack frame, saving/restoring registers and a call (branch). In other words, using
inline (when it works) is similar to writing the code for inlined function in place of its call.
inline isn't guaranteed to do anything and is compiler-dependent. The compiler will sometimes
inline functions that aren't inline (well, it's probably the linker that does that when link-time optimization is turned on, but it's easy to imagine situations when it can be done on compiler level - e.g. when the inlined function is static).
If you want to force MSVC to
inline functions, use
__forceinline and check the assembly. There should be no calls - your code should compile to simple sequence of instructions executed linearly.
Regarding the speed: you can indeed make your code faster by inlining small functions. When you
inline large functions however (and "Large" is hard to define, you need to run tests to determine what's large and what's not), your code size becomes bigger. That's because the code of the inlined function is repeated over and over again at the call sites. After all, the whole point of having a call to a function is to save the instruction count by reusing the same subroutine from multiple places in code.
When the code size becomes larger, the instruction caches may be overwhelmed, leading to slower code execution.
Another point to consider: modern out-of-order CPUs (Most desktop CPUs - e.g. Intel Core Duo or i7) have a mechanism (instruction trace) to prefetch branches ahead and "
inline" then at hardware level. So aggressive inlining doesn't always make sense.
In your example, you need to see the assembly that your compiler generates. It may be the same for the
inline and non-
inline versions. If it doesn't
__forceinline if it's MSVC that you're using. If the timing is the same in both cases, it means your CPU does a good job at prefetching instructions and the execution time bottleneck is elsewhere.