What you really want IMHO is an program transformation system, which allows you to parse and transform code using the patterns expressed in the surface syntax of the source code (and even the target language) to express the rewrites directly.
You will find that even if you can get your hands on an XML representation of the Python tree, that the effort to write an XSLT/XPath transformation is more than you expect; trees representing real code are messier than you'd expect, XSLT isn't that convenient a notation, and it cannot express directly common conditions on trees that you'd like to check (e.g., that two subtrees are the same). An final complication with XML: assume its has been transformed. How do you regenerate the source code syntax from which came? You need some kind of prettyprinter.
A general problem regardless of how the code is represented is that without information about scopes and types (where you can get it), writing correct transformations is pretty hard. After all, if you are going to transform python into a language that uses different operators for string concat and arithmetic (unlike Java which uses "+" for both), you need to be able to decide which operator to generate. So you need type information to decide. Python is arguably typeless, but in practice most expressions involve variables which have only one type for their entire lifetime. So you'll also need flow analysis to compute types.
Our DMS Software Reengineering Toolkit has all of these capabilities (parsing, flow analysis, pattern matching/rewriting, prettyprinting), and robust parsers for many languages including Python. (While it has flow analysis capability instantiated for C, COBOL, Java, this is not instantiated for Python. But then, you said you wanted to do the transformation regardless of context).
To express your rewrite in DMS on Python syntax close to your example (which isn't Python?)
= " \f(\A,(\B),(\C),(\D)) "
-> " \f(\C,(\B),(\D)) ";
The notation above is the DMS rule-rewriting language (RSL). The "..." are metaquotes that separate Python syntax (inside those quotes, DMS knows it is Python because of the domain notation declaration) from the DMS RSL language. The \n inside the meta quote refers to the syntax variable placeholders of the named nonterminal type defined in the rule parameter list. Yes, (...) inside the metaquotes are Python ( ) ... they exist in the syntax trees as far as DMS is concerned, because they, like the rest of the language, are just syntax.
The above rule looks a bit odd because I'm trying to follow your example as close as possible, and from and expression language point of view, your example is odd precisely because it does have unusual parentheses.
With this rule, DMS could parse Python (using its Python parser) like
build an AST, match the (parsed-to-AST) rule against that AST, rewrite it to another AST corresponding to:
and then prettyprint the surface syntax (valid) python back out.
If you intended your example to be a transformation on LISP code, you'd
need a LISP grammar for DMS (not hard to build, but we don't have much
call for this), and write corresponding surface syntax:
rule revise_form(A:form,B:form, C:form, D:form):form->form
= " (\A,(\B),(\C),(\D)) "
-> " (\C,(\B),(\D)) ";
You can get a better feel for this by looking at Algebra as a DMS domain.
If your goal is to implement all this in Python... I don't have much help.
DMS is a pretty big system, and it would be a lot of effort to replicate.