(* Title: HOL/Tools/datatype_realizer.ML
Author: Stefan Berghofer, TU Muenchen
Program extraction from proofs involving datatypes:
realizers for induction and case analysis.
*)
signature DATATYPE_REALIZER =
sig
val add_dt_realizers: Old_Datatype_Aux.config -> string list -> theory -> theory
end;
structure Datatype_Realizer : DATATYPE_REALIZER =
struct
fun subsets i j =
if i <= j then
let val is = subsets (i+1) j
in map (fn ks => i::ks) is @ is end
else [[]];
fun is_unit t = body_type (fastype_of t) = HOLogic.unitT;
fun tname_of (Type (s, _)) = s
| tname_of _ = "";
fun make_ind ({descr, rec_names, rec_rewrites, induct, ...} : Old_Datatype_Aux.info) is thy =
let
val ctxt = Proof_Context.init_global thy;
val recTs = Old_Datatype_Aux.get_rec_types descr;
val pnames =
if length descr = 1 then ["P"]
else map (fn i => "P" ^ string_of_int i) (1 upto length descr);
val rec_result_Ts = map (fn ((i, _), P) =>
if member (op =) is i then TFree ("'" ^ P, @{sort type}) else HOLogic.unitT)
(descr ~~ pnames);
fun make_pred i T U r x =
if member (op =) is i then
Free (nth pnames i, T --> U --> HOLogic.boolT) $ r $ x
else Free (nth pnames i, U --> HOLogic.boolT) $ x;
fun mk_all i s T t =
if member (op =) is i then Logic.all (Free (s, T)) t else t;
val (prems, rec_fns) = split_list (flat (fst (fold_map
(fn ((i, (_, _, constrs)), T) => fold_map (fn (cname, cargs) => fn j =>
let
val Ts = map (Old_Datatype_Aux.typ_of_dtyp descr) cargs;
val tnames = Name.variant_list pnames (Old_Datatype_Prop.make_tnames Ts);
val recs = filter (Old_Datatype_Aux.is_rec_type o fst o fst) (cargs ~~ tnames ~~ Ts);
val frees = tnames ~~ Ts;
fun mk_prems vs [] =
let
val rT = nth (rec_result_Ts) i;
val vs' = filter_out is_unit vs;
val f = Old_Datatype_Aux.mk_Free "f" (map fastype_of vs' ---> rT) j;
val f' =
Envir.eta_contract (fold_rev (absfree o dest_Free) vs
(if member (op =) is i then list_comb (f, vs') else HOLogic.unit));
in
(HOLogic.mk_Trueprop (make_pred i rT T (list_comb (f, vs'))
(list_comb (Const (cname, Ts ---> T), map Free frees))), f')
end
| mk_prems vs (((dt, s), T) :: ds) =
let
val k = Old_Datatype_Aux.body_index dt;
val (Us, U) = strip_type T;
val i = length Us;
val rT = nth (rec_result_Ts) k;
val r = Free ("r" ^ s, Us ---> rT);
val (p, f) = mk_prems (vs @ [r]) ds;
in
(mk_all k ("r" ^ s) (Us ---> rT) (Logic.mk_implies
(Logic.list_all (map (pair "x") Us, HOLogic.mk_Trueprop
(make_pred k rT U (Old_Datatype_Aux.app_bnds r i)
(Old_Datatype_Aux.app_bnds (Free (s, T)) i))), p)), f)
end;
in (apfst (fold_rev (Logic.all o Free) frees) (mk_prems (map Free frees) recs), j + 1) end)
constrs) (descr ~~ recTs) 1)));
fun mk_proj _ [] t = t
| mk_proj j (i :: is) t =
if null is then t
else if (j: int) = i then HOLogic.mk_fst t
else mk_proj j is (HOLogic.mk_snd t);
val tnames = Old_Datatype_Prop.make_tnames recTs;
val fTs = map fastype_of rec_fns;
val ps = map (fn ((((i, _), T), U), s) => Abs ("x", T, make_pred i U T
(list_comb (Const (s, fTs ---> T --> U), rec_fns) $ Bound 0) (Bound 0)))
(descr ~~ recTs ~~ rec_result_Ts ~~ rec_names);
val r =
if null is then Extraction.nullt
else
foldr1 HOLogic.mk_prod (map_filter (fn (((((i, _), T), U), s), tname) =>
if member (op =) is i then SOME
(list_comb (Const (s, fTs ---> T --> U), rec_fns) $ Free (tname, T))
else NONE) (descr ~~ recTs ~~ rec_result_Ts ~~ rec_names ~~ tnames));
val concl =
HOLogic.mk_Trueprop (foldr1 (HOLogic.mk_binop @{const_name HOL.conj})
(map (fn ((((i, _), T), U), tname) =>
make_pred i U T (mk_proj i is r) (Free (tname, T)))
(descr ~~ recTs ~~ rec_result_Ts ~~ tnames)));
val inst =
map (#1 o dest_Var o head_of)
(HOLogic.dest_conj (HOLogic.dest_Trueprop (Thm.concl_of induct))) ~~
map (Thm.cterm_of ctxt) ps;
val thm =
Goal.prove_internal ctxt (map (Thm.cterm_of ctxt) prems) (Thm.cterm_of ctxt concl)
(fn prems =>
EVERY [
rewrite_goals_tac ctxt (map mk_meta_eq [@{thm fst_conv}, @{thm snd_conv}]),
resolve_tac ctxt [infer_instantiate ctxt inst induct] 1,
ALLGOALS (Object_Logic.atomize_prems_tac ctxt),
rewrite_goals_tac ctxt (@{thm o_def} :: map mk_meta_eq rec_rewrites),
REPEAT ((resolve_tac ctxt prems THEN_ALL_NEW (fn i =>
REPEAT (eresolve_tac ctxt [allE] i) THEN assume_tac ctxt i)) 1)])
|> Drule.export_without_context;
val ind_name = Thm.derivation_name induct;
val vs = map (nth pnames) is;
val (thm', thy') = thy
|> Sign.root_path
|> Global_Theory.store_thm
(Binding.qualified_name (space_implode "_" (ind_name :: vs @ ["correctness"])), thm)
||> Sign.restore_naming thy;
val ctxt' = Proof_Context.init_global thy';
val ivs = rev (Term.add_vars (Logic.varify_global (Old_Datatype_Prop.make_ind [descr])) []);
val rvs = rev (Thm.fold_terms Term.add_vars thm' []);
val ivs1 = map Var (filter_out (fn (_, T) => @{type_name bool} = tname_of (body_type T)) ivs);
val ivs2 = map (fn (ixn, _) => Var (ixn, the (AList.lookup (op =) rvs ixn))) ivs;
val prf =
Extraction.abs_corr_shyps thy' induct vs ivs2
(fold_rev (fn (f, p) => fn prf =>
(case head_of (strip_abs_body f) of
Free (s, T) =>
let val T' = Logic.varifyT_global T in
Abst (s, SOME T', Proofterm.prf_abstract_over
(Var ((s, 0), T')) (AbsP ("H", SOME p, prf)))
end
| _ => AbsP ("H", SOME p, prf)))
(rec_fns ~~ Thm.prems_of thm)
(Proofterm.proof_combP
(Reconstruct.proof_of ctxt' thm', map PBound (length prems - 1 downto 0))));
val r' =
if null is then r
else
Logic.varify_global (fold_rev lambda
(map Logic.unvarify_global ivs1 @ filter_out is_unit
(map (head_of o strip_abs_body) rec_fns)) r);
in Extraction.add_realizers_i [(ind_name, (vs, r', prf))] thy' end;
fun make_casedists ({index, descr, case_name, case_rewrites, exhaust, ...} : Old_Datatype_Aux.info) thy =
let
val ctxt = Proof_Context.init_global thy;
val rT = TFree ("'P", @{sort type});
val rT' = TVar (("'P", 0), @{sort type});
fun make_casedist_prem T (cname, cargs) =
let
val Ts = map (Old_Datatype_Aux.typ_of_dtyp descr) cargs;
val frees = Name.variant_list ["P", "y"] (Old_Datatype_Prop.make_tnames Ts) ~~ Ts;
val free_ts = map Free frees;
val r = Free ("r" ^ Long_Name.base_name cname, Ts ---> rT)
in
(r, fold_rev Logic.all free_ts
(Logic.mk_implies (HOLogic.mk_Trueprop
(HOLogic.mk_eq (Free ("y", T), list_comb (Const (cname, Ts ---> T), free_ts))),
HOLogic.mk_Trueprop (Free ("P", rT --> HOLogic.boolT) $
list_comb (r, free_ts)))))
end;
val SOME (_, _, constrs) = AList.lookup (op =) descr index;
val T = nth (Old_Datatype_Aux.get_rec_types descr) index;
val (rs, prems) = split_list (map (make_casedist_prem T) constrs);
val r = Const (case_name, map fastype_of rs ---> T --> rT);
val y = Var (("y", 0), Logic.varifyT_global T);
val y' = Free ("y", T);
val thm =
Goal.prove_internal ctxt (map (Thm.cterm_of ctxt) prems)
(Thm.cterm_of ctxt
(HOLogic.mk_Trueprop (Free ("P", rT --> HOLogic.boolT) $ list_comb (r, rs @ [y']))))
(fn prems =>
EVERY [
resolve_tac ctxt [infer_instantiate ctxt [(#1 (dest_Var y), Thm.cterm_of ctxt y')] exhaust] 1,
ALLGOALS (EVERY'
[asm_simp_tac (put_simpset HOL_basic_ss ctxt addsimps case_rewrites),
resolve_tac ctxt prems, asm_simp_tac (put_simpset HOL_basic_ss ctxt)])])
|> Drule.export_without_context;
val exh_name = Thm.derivation_name exhaust;
val (thm', thy') = thy
|> Sign.root_path
|> Global_Theory.store_thm (Binding.qualified_name (exh_name ^ "_P_correctness"), thm)
||> Sign.restore_naming thy;
val ctxt' = Proof_Context.init_global thy';
val P = Var (("P", 0), rT' --> HOLogic.boolT);
val prf =
Extraction.abs_corr_shyps thy' exhaust ["P"] [y, P]
(fold_rev (fn (p, r) => fn prf =>
Proofterm.forall_intr_proof' (Logic.varify_global r)
(AbsP ("H", SOME (Logic.varify_global p), prf)))
(prems ~~ rs)
(Proofterm.proof_combP
(Reconstruct.proof_of ctxt' thm', map PBound (length prems - 1 downto 0))));
val prf' =
Extraction.abs_corr_shyps thy' exhaust []
(map Var (Term.add_vars (Thm.prop_of exhaust) [])) (Reconstruct.proof_of ctxt' exhaust);
val r' =
Logic.varify_global (Abs ("y", T,
(fold_rev (Term.abs o dest_Free) rs
(list_comb (r, map Bound ((length rs - 1 downto 0) @ [length rs]))))));
in
Extraction.add_realizers_i
[(exh_name, (["P"], r', prf)),
(exh_name, ([], Extraction.nullt, prf'))] thy'
end;
fun add_dt_realizers config names thy =
if not (Proofterm.proofs_enabled ()) then thy
else
let
val _ = Old_Datatype_Aux.message config "Adding realizers for induction and case analysis ...";
val infos = map (BNF_LFP_Compat.the_info thy []) names;
val info :: _ = infos;
in
thy
|> fold_rev (perhaps o try o make_ind info) (subsets 0 (length (#descr info) - 1))
|> fold_rev (perhaps o try o make_casedists) infos
end;
val _ = Theory.setup (BNF_LFP_Compat.interpretation @{plugin extraction} [] add_dt_realizers);
end;