I would like to take Emacs Lisp code that has been macro expanded and unmacro expand it.
Macros generate arbitrary expressions, which may contain macros recursively. You have no general way to revert the transformations, because it's not pattern-based.
Even if macros were pattern-based, they could still be infinite.
Even if macros were not infinite, they can certainly contain bugs in expansions of patterns that never matched. Given arbitrary code to try to unwind, it could match an expansion that looks like the code and try to revert to its pattern. Without bugs, you could still abuse this.
Even if you could revert macro expansion, some macros expand to the same code. An approach could be signalling a warning with a restart when all reversions expand equally minus the operator, such that if the restart doesn't handle the signal, it would choose the first expansion; and otherwise signalling an error with a restart, such that if the restart doesn't handle the signal, it errors. Or you could configure it to choose certain macros under certain conditions, such as in which package the code was found.
In practice, there are very few cases where reverting an expansion makes any sense. It could be a useful development tool that suggests macros, but I wouldn't generally rely on it for whole source transformations.
One way you could achieve what you want is through a controlled pattern matching. You could initially create patterns manually, which would already handle cases you care about directly, such as the ones you mention:
(if (not <cond>) <expr>) and
(if (not <cond>) (progn <&expr>)) to
(unless <cond> <&expr>)
You'd have to decide whether
null would be equivalent to
not. I personally don't mix the boolean meaning of
nil with that of empty list or something else, e.g. no result, nothing found, null object, a designator, etc. But perhaps Lisp code as old as that in Emacs just uses them interchangeably.
(if <cond> <expr>) and
(if <cond> (progn <&expr>)) to
(when <cond> <&expr>)
If you feel like improving code overall, include
cond with a single condition. And be careful with cond clauses with only the condition.
You should have a few dozen more, to see how the pattern matching behaves with more patterns to match in terms of time (CPU) and space (memory).
From the description of fare-quasiquote, optima doesn't support backtracking, which you probably want.
But you can do backtracking with optima by yourself, using recursion on complex inner patterns, and if nothing matches, return a control value to keep searching for matching patterns from the outer input.
Another approach is to treat a pattern as a description of a state machine, and handle each new token to advance the current state machines until one of them reaches the end, discarding the state machines that couldn't advance. This approach may consume more memory, depending on the amount of patterns, the similarity between patterns (if many have the same starting token, many state machines will be generated on a matching token), the length of the patterns and, last but not least, the length of the input (s-expression).
An advantage of this approach is that you can use it interactively to see which patterns have matched the most tokens, and you can give weights to patterns instead of just taking the first that matches.
A disadvantage is that, most probably, you'll have to spend effort to develop it.
EDIT: I just lousily described a kind of trie or radix tree.
Once you got something working, maybe try to obtain patterns automatically. This is really hard, you must probably limit it to simple backquoting and accept the fact you can't generalize for anything that contains more complex code.
I believe the hardest will be code walking, which is hard enough with source code, but much more with macro-expanded code. Perhaps if you could expand the whole picture a bit further to understand the goal, maybe someone could suggest a better approach other than operating on macro-expanded code.
However one would think that this kind of thing, S-expression transformation, is right up Lisp's alley. And
defmacro is I believe available in Lisp as it is in Emacs Lisp.
So surely there are program transformation systems, or term-rewriting systems that can be adapted here.
There's a huge step from expanding code with
defmacro and all that generality. Most Lisp developers will know about hygienic macros, at least in terms of symbols as variables.
But there's still hygienic macros in terms of symbols as operators1, code walking, interaction with a containing macro (usually using
macrolet), etc. It's way too complex.
Common Lisp evaluates the operator in a compound form in the lexical environment, and probably everyone makes macros that assume that the global macro or function definition of a symbol will be used.
But it might not be so:
(defmacro my-macro-1 ()
(defmacro my-macro-2 ()
(defun my-function (n)
(* n 100))
(macrolet ((my-macro-1 ()
(flet ((my-function (n)
(* n 1000)))
That last line will expand to
(my-function (my-macro-2)), which will be recursively expanded to
(my-function 2). When evaluated, it will yield 2000.
For proper operator hygiene, you'd have to do something like this:
(defmacro my-macro-2 ()
;; capture global bindings of my-macro-1 and my-function-1 by name
(flet ((my-macro-1-global (form env)
(funcall (macro-function 'my-macro-1) form env))
(my-function-global (&rest args)
;; hope the compiler can optimize this
(apply 'my-function args)))
;; store them globally in uninterned symbols
;; hopefully, no one will mess with them
(let ((my-macro-1-symbol (gensym (symbol-name 'my-macro-1)))
(my-function-symbol (gensym (symbol-name 'my-function))))
(setf (macro-function my-macro-1-symbol) #'my-macro-1-global)
(setf (symbol-function my-function-symbol) #'my-function-global)
With this definition, the example will yield 100.
Common Lisp has some restrictions to avoid this, but it only states the consequences are undefined when (re)defining symbols in the
common-lisp package, globally or locally. It doesn't require errors or warnings to be signaled.