Note: this answer is for C++. For C, see caf's answer. The two languages differ.
static has two relevant meanings:
For a function at namespace scope,
static gives the function internal linkage, which in practical terms means that the name is not visible to the linker.
static can also be used this way for data, but for data this usage was deprecated in C++03 (§D.2 in C++03 Annex D, normative). Still, constants have internal linkage by default (it's not a good idea to make that explicit, since the usage for data is deprecated).
For a function in a class,
static removes the implicit
this argument, so that the function can be called without an object of the class.
In a header one would usually not use internal linkage for functions, because one doesn't want a function to be duplicated in every compilation unit where the header is included.
A common convention is to instead use a nested namespace called
detail, when one needs classes or functions that are not part of the public module interface, and wants to reduce the pollution the ordinary namespace (i.e., reduce the potential for name conflict). This convention is used by the Boost library. In the same way as with include guard symbols this convention signifies a lack of module support in current C++, where one is essentially reduced to simulating some crucial language features via conventions.
inline also has two relevant meanings:
For a function at namespace scope it tells the compiler that the definition of the function is intentionally provided in every compilation unit where it’s used. In practical terms this makes the linker ignore multiple definitions of the function, and makes it possible to define non-template functions in header files. There is no corresponding language feature for data, although templates can be used to simulate the
inline effect for data.
It also, unfortunately, gives the compiler a strong hint that calls to the function should preferably be expanded “inline” in the machine code.
The first meaning is the only guaranteed meaning of
In general, apply
inline to every function definition in a header file. There is one exception, namely a function defined directly in a class definition. Such a function is automatically declared
inline (i.e., you avoid linker protests without explicitly adding the word
inline, so that one practical usage in this context is to apply
inline to a function declaration within a class, to tell a reader that a definition of that function follows later in the header file).
So, while it appears that you are a bit confused about the meanings of
inline – they're not interchangable! – you’re essentially right that
inline are somehow connected. Moving a (free) function out of a class to namespace scope, you would change
inline, and moving a function from namespace scope into a class, you would change
static. Although it isn’t a common thing to do, I have found it to be not uncommon while refactoring header-only code.
inline for every namespace scope function defined in a header. In particular, do use
inline for a specialization of a function template, since function templates can only be fully specialized, and the full specialization is an ordinary function. Failure to apply
inline to a function template specialization in a header file, will in general cause linking errors.
Use some special nested namespace e.g. called
detail to avoid pollution with internal implementation detail names.
static for static class members.
static to make explicit that a constant has internal linkage, because this use of
static is deprecated in C++03 (even though apparently the deprecation was removed in C++11).
Keep in mind that while
inline can’t be applied to data, it is possible to achieve just about the same (in-practice) effect by using templates. But where you do need some big chunk of shared constant data, implemented in a header, I recommend producing a reference to the data via an
inline function. It’s much easier to code up, and much easier to understand for a reader of the code. :-)