The use of macros like
DEFER, and complicated C macrology in general, depends on understanding how the C preprocessor actually expands macro expressions. It doesn't just attempt to reduce all expression trees the way a conventional programming language does, but rather, it works on a linear token stream, and has an implicit "cursor" at the point where it's currently examining the stream for possible replacements. Within any given "stack frame" of the expansion process, the cursor never moves backwards, and once a token has been passed in the stream it is not examined again.
Walking through the first example of
DEFER(A)() // cursor starts at the head of the sequence
^ // identifies call to DEFER - push current position
DEFER( A )() // attempt to expand the argument (nothing to do)
// replace occurrences of id in DEFER with A,
// then replace the call to it with the substituted body
A EMPTY() () // pop cursor position (start of pasted subsequence)
^ // doesn't find an expansion for A, move on
A EMPTY() () // move to next token
^ // EMPTY() is a valid expansion
A () // replace EMPTY() with its body in the same way
^ // continuing...
A () // `(` is not a macro, move on
A ( ) // `)` is not a macro, move on
A () // end of sequence, no more expansions
The cursor moved past
A during the "rescan" of
DEFER's body, after the arguments had been substituted, which is the second and last attempt to expand that set of tokens. Once the cursor has moved past
A it does not return to it during that expansion sequence, and since the "rescan" is at the top level there is no following expansion sequence.
Now consider the same expression, but wrapped in a call to
EXPAND(DEFER(A)()) // cursor starts at the head etc.
^ // identifies call to EXPAND
EXPAND( DEFER(A)() ) // attempt to expand the argument
^ // this does the same as the first
// example, in a NESTED CONTEXT
// replace occurrences of __VA_ARGS__ in EXPAND with A ()
// then replace the call with the substituted body
A () // pop cursor position (start of pasted subsequence)
^ // identifies A, and can expand it this time
Because argument lists are expanded in a stacked context, and the cursor position is restored to the position in front of the original call for the rescan pass, placing a macro invocation in any macro's argument list - even one that actually does nothing, like
EXPAND - gives it a "free" extra run over by the expansion cursor, by resetting the cursor's position in the stream an extra time for an extra rescan pass, and therefore giving each freshly constructed call expression (i.e. the pushing together of a macro name and a parenthesized argument list) an extra chance at being recognised by the expander. So all
EVAL does is give you 363 (3^5+3^4+3^3+3^2+3, someone check my math) free rescan passes.
So, addressing the questions in light of this:
- "painting blue" doesn't work quite like that (the explanation in the wiki is a bit misleadingly phrased, although it's not wrong). The name of a macro, if generated within that macro, will be painted blue permanently (C11 220.127.116.11 "[blue] tokens are no longer available for further replacement even if they are later (re)examined"). The point of
DEFER is rather to ensure that the recursive invocation doesn't get generated on the macro's expansion pass, but instead is ...deferred... until an outer rescan step, at which point it won't get painted blue because we're no longer within that named macro. This is why
REPEAT_INDIRECT is function-like; so that it can be prevented from expanding into anything mentioning the name of
REPEAT, as long as we're still within the body of
REPEAT. It requires at least one further free pass after the originating
REPEAT completes to expand away the spacing
EXPAND forces an additional expansion pass. Any macro invocation grants one extra expansion pass to whatever expression was passed in its argument list.
- the idea of
DEFER is that you don't pass it a whole expression, just the "function" part; it inserts a spacer between the function and its argument list that costs one expansion pass to remove.
- therefore the difference between
DEFER is that
DEFER imposes the need for an extra pass, before the function you pass it gets expanded; and
EXPAND provides that extra pass. So they are each other's inverse (and applied together, as in the first example, are equivalent to a call using neither).
OBSTRUCT costs two expansion passes before the function you pass it gets expanded. It does this by
DEFERing the expansion of the
EMPTY() spacer by one (
EMPTY EMPTY() ()), burning the first cursor reset on getting rid of the nested
OBSTRUCT is needed around
WHEN expands (on true) to a call to
EXPAND, which will burn away one layer of indirection while we're still within the call to
REPEAT. If there was only one layer (a
DEFER), the nested
REPEAT would be generated while we're still in
REPEAT's context, causing it to be painted blue and killing the recursion right there. Using two layers with
OBSTRUCT means that the nested
REPEAT won't be generated until we reach the rescan pass of whatever macro call is outside
REPEAT, at which point we can safely generate the name again without it being painted blue, because it's been popped from the no-expand stack.
So, this method of recursion works by using an external source of a large number of rescan passes (
EVAL), and deferring the expansion of a macro's name within itself by at least one rescan pass so it happens further down the call stack. The first expansion of the body of
REPEAT happens during the rescan of
EVAL, the recursive invocation is deferred until the rescan of
EVAL, the nested expansion deferred... and so on. It's not true recursion, as it can't form an infinite loop, but instead relies on an external source of stack frames to burn through.