Has anyone written a formal paper describing a method to (automatically) convert functions to be tail recursive? I am looking for a university-level formal treatment including the limitations (types of functions that can be converted), procedures for conversion, and, if possible, proofs of correctness? Examples in Haskell would be a bonus.
So there are two parts to this:
Transforming recursion into tail recursion
It appears relatively straight forward to recognize tail recursive definitions syntactically. After all, 'tail recursive' just means that the call appears syntactically in the tail of the expression.
E.g. the Scheme folks describe:
Transforming functions into tail calls
The tricky part of your question is optimizations for identifying and transforming candidate recursive computations into tail recursive ones.
One reference is in GHC, which uses inlining and a wide array of simplification rules to collapse away recursive calls, until their underlying tail recursive structure remains.
Tail Call Elimination
Once you have your functions in a tail-recursive form, you'd like to have that implemented effiicently. If you can generate a loop, that's a good start. If your target machine doesn't, then the tail call elimination" will need a few tricks. To quote Odersky and Schinz, cited below,
Mercury contains a couple of optimizations for automatically making things tail-recursive. (Mercury is an enforce-purity logic programming language, so it talks about predicates rather than functions, but many of the same ideas apply to Mercury programs as to Haskell ones. A much bigger difference than it being logical rather than functional is that it is strict rather than lazy)
"Accumulator introduction" generates specialised versions of predicates with an extra accumulator parameter in order to allow associative operations to be moved before the recursive call. Apparently this optimisation doesn't necessarily result in tail-recursive predicates on its own, but often results in a form which can be optimised by the second optimisation:
"Last call modulo constructors" essentially allows a recursive call that is followed only by constructor applications to be rewritten such that the value is constructed first containing a "hole" and then the recursive call returns its output directly into the memory address of the "hole" rather than using the normal return-value-passing convention. I believe Haskell would get this optimisation for free simply due to laziness, however.
Both of these optimisations are described in the paper Making Mercury programs tail recursive.