(* Author: Jia Meng, Cambridge University Computer Laboratory
ID: $Id$
Copyright 2004 University of Cambridge
Transformation of axiom rules (elim/intro/etc) into CNF forms.
*)
(*FIXME: does this signature serve any purpose?*)
signature RES_AXIOMS =
sig
val elimRule_tac : thm -> Tactical.tactic
val elimR2Fol : thm -> term
val transform_elim : thm -> thm
val cnf_axiom : (string * thm) -> thm list
val meta_cnf_axiom : thm -> thm list
val claset_rules_of_thy : theory -> (string * thm) list
val simpset_rules_of_thy : theory -> (string * thm) list
val claset_rules_of_ctxt: Proof.context -> (string * thm) list
val simpset_rules_of_ctxt : Proof.context -> (string * thm) list
val pairname : thm -> (string * thm)
val skolem_thm : thm -> thm list
val to_nnf : thm -> thm
val cnf_rules_pairs : (string * Thm.thm) list -> (Thm.thm * (string * int)) list list;
val meson_method_setup : theory -> theory
val setup : theory -> theory
val atpset_rules_of_thy : theory -> (string * thm) list
val atpset_rules_of_ctxt : Proof.context -> (string * thm) list
end;
structure ResAxioms =
struct
(*FIXME DELETE: For running the comparison between combinators and abstractions.
CANNOT be a ref, as the setting is used while Isabelle is built.*)
val abstract_lambdas = true;
val trace_abs = ref false;
(*Store definitions of abstraction functions, ensuring that identical right-hand
sides are denoted by the same functions and thereby reducing the need for
extensionality in proofs.
FIXME! Store in theory data!!*)
val abstraction_cache = ref Net.empty : thm Net.net ref;
(**** Transformation of Elimination Rules into First-Order Formulas****)
(* a tactic used to prove an elim-rule. *)
fun elimRule_tac th =
(resolve_tac [impI,notI] 1) THEN (etac th 1) THEN REPEAT(fast_tac HOL_cs 1);
fun add_EX tm [] = tm
| add_EX tm ((x,xtp)::xs) = add_EX (HOLogic.exists_const xtp $ Abs(x,xtp,tm)) xs;
(*Checks for the premise ~P when the conclusion is P.*)
fun is_neg (Const("Trueprop",_) $ (Const("Not",_) $ Free(p,_)))
(Const("Trueprop",_) $ Free(q,_)) = (p = q)
| is_neg _ _ = false;
exception ELIMR2FOL;
(*Handles the case where the dummy "conclusion" variable appears negated in the
premises, so the final consequent must be kept.*)
fun strip_concl' prems bvs (Const ("==>",_) $ P $ Q) =
strip_concl' (HOLogic.dest_Trueprop P :: prems) bvs Q
| strip_concl' prems bvs P =
let val P' = HOLogic.Not $ (HOLogic.dest_Trueprop P)
in add_EX (foldr1 HOLogic.mk_conj (P'::prems)) bvs end;
(*Recurrsion over the minor premise of an elimination rule. Final consequent
is ignored, as it is the dummy "conclusion" variable.*)
fun strip_concl prems bvs concl (Const ("all", _) $ Abs (x,xtp,body)) =
strip_concl prems ((x,xtp)::bvs) concl body
| strip_concl prems bvs concl (Const ("==>",_) $ P $ Q) =
if (is_neg P concl) then (strip_concl' prems bvs Q)
else strip_concl (HOLogic.dest_Trueprop P::prems) bvs concl Q
| strip_concl prems bvs concl Q =
if concl aconv Q then add_EX (foldr1 HOLogic.mk_conj prems) bvs
else raise ELIMR2FOL (*expected conclusion not found!*)
fun trans_elim (major,[],_) = HOLogic.Not $ major
| trans_elim (major,minors,concl) =
let val disjs = foldr1 HOLogic.mk_disj (map (strip_concl [] [] concl) minors)
in HOLogic.mk_imp (major, disjs) end;
(* convert an elim rule into an equivalent formula, of type term. *)
fun elimR2Fol elimR =
let val elimR' = #1 (Drule.freeze_thaw elimR)
val (prems,concl) = (prems_of elimR', concl_of elimR')
val cv = case concl of (*conclusion variable*)
Const("Trueprop",_) $ (v as Free(_,Type("bool",[]))) => v
| v as Free(_, Type("prop",[])) => v
| _ => raise ELIMR2FOL
in case prems of
[] => raise ELIMR2FOL
| (Const("Trueprop",_) $ major) :: minors =>
if member (op aconv) (term_frees major) cv then raise ELIMR2FOL
else (trans_elim (major, minors, concl) handle TERM _ => raise ELIMR2FOL)
| _ => raise ELIMR2FOL
end;
(* convert an elim-rule into an equivalent theorem that does not have the
predicate variable. Leave other theorems unchanged.*)
fun transform_elim th =
let val ctm = cterm_of (sign_of_thm th) (HOLogic.mk_Trueprop (elimR2Fol th))
in Goal.prove_raw [] ctm (fn _ => elimRule_tac th) end
handle ELIMR2FOL => th (*not an elimination rule*)
| exn => (warning ("transform_elim failed: " ^ Toplevel.exn_message exn ^
" for theorem " ^ string_of_thm th); th)
(**** Transformation of Clasets and Simpsets into First-Order Axioms ****)
(*Transfer a theorem into theory Reconstruction.thy if it is not already
inside that theory -- because it's needed for Skolemization *)
(*This will refer to the final version of theory Reconstruction.*)
val recon_thy_ref = Theory.self_ref (the_context ());
(*If called while Reconstruction is being created, it will transfer to the
current version. If called afterward, it will transfer to the final version.*)
fun transfer_to_Reconstruction th =
transfer (Theory.deref recon_thy_ref) th handle THM _ => th;
fun is_taut th =
case (prop_of th) of
(Const ("Trueprop", _) $ Const ("True", _)) => true
| _ => false;
(* remove tautologous clauses *)
val rm_redundant_cls = List.filter (not o is_taut);
(**** SKOLEMIZATION BY INFERENCE (lcp) ****)
(*Traverse a theorem, declaring Skolem function definitions. String s is the suggested
prefix for the Skolem constant. Result is a new theory*)
fun declare_skofuns s th thy =
let fun dec_sko (Const ("Ex",_) $ (xtp as Abs(_,T,p))) (thy, axs) =
(*Existential: declare a Skolem function, then insert into body and continue*)
let val cname = gensym ("sko_" ^ s ^ "_")
val args = term_frees xtp (*get the formal parameter list*)
val Ts = map type_of args
val cT = Ts ---> T
val c = Const (Sign.full_name thy cname, cT)
val rhs = list_abs_free (map dest_Free args, HOLogic.choice_const T $ xtp)
(*Forms a lambda-abstraction over the formal parameters*)
val thy' = Theory.add_consts_i [(cname, cT, NoSyn)] thy
(*Theory is augmented with the constant, then its def*)
val cdef = cname ^ "_def"
val thy'' = Theory.add_defs_i false false [(cdef, equals cT $ c $ rhs)] thy'
in dec_sko (subst_bound (list_comb(c,args), p))
(thy'', get_axiom thy'' cdef :: axs)
end
| dec_sko (Const ("All",_) $ (xtp as Abs(a,T,p))) thx =
(*Universal quant: insert a free variable into body and continue*)
let val fname = Name.variant (add_term_names (p,[])) a
in dec_sko (subst_bound (Free(fname,T), p)) thx end
| dec_sko (Const ("op &", _) $ p $ q) thx = dec_sko q (dec_sko p thx)
| dec_sko (Const ("op |", _) $ p $ q) thx = dec_sko q (dec_sko p thx)
| dec_sko (Const ("Trueprop", _) $ p) thx = dec_sko p thx
| dec_sko t thx = thx (*Do nothing otherwise*)
in dec_sko (prop_of th) (thy,[]) end;
(*Traverse a theorem, accumulating Skolem function definitions.*)
fun assume_skofuns th =
let fun dec_sko (Const ("Ex",_) $ (xtp as Abs(_,T,p))) defs =
(*Existential: declare a Skolem function, then insert into body and continue*)
let val skos = map (#1 o Logic.dest_equals) defs (*existing sko fns*)
val args = term_frees xtp \\ skos (*the formal parameters*)
val Ts = map type_of args
val cT = Ts ---> T
val c = Free (gensym "sko_", cT)
val rhs = list_abs_free (map dest_Free args,
HOLogic.choice_const T $ xtp)
(*Forms a lambda-abstraction over the formal parameters*)
val def = equals cT $ c $ rhs
in dec_sko (subst_bound (list_comb(c,args), p))
(def :: defs)
end
| dec_sko (Const ("All",_) $ (xtp as Abs(a,T,p))) defs =
(*Universal quant: insert a free variable into body and continue*)
let val fname = Name.variant (add_term_names (p,[])) a
in dec_sko (subst_bound (Free(fname,T), p)) defs end
| dec_sko (Const ("op &", _) $ p $ q) defs = dec_sko q (dec_sko p defs)
| dec_sko (Const ("op |", _) $ p $ q) defs = dec_sko q (dec_sko p defs)
| dec_sko (Const ("Trueprop", _) $ p) defs = dec_sko p defs
| dec_sko t defs = defs (*Do nothing otherwise*)
in dec_sko (prop_of th) [] end;
(**** REPLACING ABSTRACTIONS BY FUNCTION DEFINITIONS ****)
(*Returns the vars of a theorem*)
fun vars_of_thm th =
map (Thm.cterm_of (theory_of_thm th) o Var) (Drule.fold_terms Term.add_vars th []);
(*Make a version of fun_cong with a given variable name*)
local
val fun_cong' = fun_cong RS asm_rl; (*renumber f, g to prevent clashes with (a,0)*)
val cx = hd (vars_of_thm fun_cong');
val ty = typ_of (ctyp_of_term cx);
val thy = theory_of_thm fun_cong;
fun mkvar a = cterm_of thy (Var((a,0),ty));
in
fun xfun_cong x = Thm.instantiate ([], [(cx, mkvar x)]) fun_cong'
end;
(*Removes the lambdas from an equation of the form t = (%x. u)*)
fun strip_lambdas th =
case prop_of th of
_ $ (Const ("op =", _) $ _ $ Abs (x,_,_)) =>
strip_lambdas (#1 (Drule.freeze_thaw (th RS xfun_cong x)))
| _ => th;
(*Convert meta- to object-equality. Fails for theorems like split_comp_eq,
where some types have the empty sort.*)
fun object_eq th = th RS def_imp_eq
handle THM _ => error ("Theorem contains empty sort: " ^ string_of_thm th);
fun valid_name vs (Free(x,T)) = x mem_string vs
| valid_name vs _ = false;
(*Contract all eta-redexes in the theorem, lest they give rise to needless abstractions*)
fun eta_conversion_rule th =
equal_elim (eta_conversion (cprop_of th)) th;
fun crhs_of th =
case Drule.strip_comb (cprop_of th) of
(f, [_, rhs]) =>
(case term_of f of Const ("==", _) => rhs
| _ => raise THM ("crhs_of", 0, [th]))
| _ => raise THM ("crhs_of", 1, [th]);
fun rhs_of th =
case prop_of th of (Const("==",_) $ _ $ rhs) => rhs
| _ => raise THM ("rhs_of", 1, [th]);
(*Apply a function definition to an argument, beta-reducing the result.*)
fun beta_comb cf x =
let val th1 = combination cf (reflexive x)
val th2 = beta_conversion false (crhs_of th1)
in transitive th1 th2 end;
(*Apply a function definition to arguments, beta-reducing along the way.*)
fun list_combination cf [] = cf
| list_combination cf (x::xs) = list_combination (beta_comb cf x) xs;
fun list_cabs ([] , t) = t
| list_cabs (v::vars, t) = Thm.cabs v (list_cabs(vars,t));
fun assert_eta_free ct =
let val t = term_of ct
in if (t aconv Envir.eta_contract t) then ()
else error ("Eta redex in term: " ^ string_of_cterm ct)
end;
fun eq_absdef (th1, th2) =
Context.joinable (theory_of_thm th1, theory_of_thm th2) andalso
rhs_of th1 aconv rhs_of th2;
fun lambda_free (Abs _) = false
| lambda_free (t $ u) = lambda_free t andalso lambda_free u
| lambda_free _ = true;
fun monomorphic t =
Term.fold_types (Term.fold_atyps (fn TVar _ => K false | _ => I)) t true;
(*Traverse a theorem, declaring abstraction function definitions. String s is the suggested
prefix for the constants. Resulting theory is returned in the first theorem. *)
fun declare_absfuns th =
let fun abstract thy ct =
if lambda_free (term_of ct) then (transfer thy (reflexive ct), [])
else
case term_of ct of
Abs (_,T,u) =>
let val cname = gensym "abs_"
val _ = assert_eta_free ct;
val (cv,cta) = Thm.dest_abs NONE ct
val v = (#1 o dest_Free o term_of) cv
val (u'_th,defs) = abstract thy cta
val cu' = crhs_of u'_th
val abs_v_u = lambda (term_of cv) (term_of cu')
(*get the formal parameters: ALL variables free in the term*)
val args = term_frees abs_v_u
val rhs = list_abs_free (map dest_Free args, abs_v_u)
(*Forms a lambda-abstraction over the formal parameters*)
val v_rhs = Logic.varify rhs
val (ax,thy) =
case List.find (fn ax => v_rhs aconv rhs_of ax)
(Net.match_term (!abstraction_cache) v_rhs) of
SOME ax => (ax,thy) (*cached axiom, current theory*)
| NONE =>
let val Ts = map type_of args
val cT = Ts ---> (T --> typ_of (ctyp_of_term cu'))
val thy = theory_of_thm u'_th
val c = Const (Sign.full_name thy cname, cT)
val thy = Theory.add_consts_i [(cname, cT, NoSyn)] thy
(*Theory is augmented with the constant,
then its definition*)
val cdef = cname ^ "_def"
val thy = Theory.add_defs_i false false
[(cdef, equals cT $ c $ rhs)] thy
val ax = get_axiom thy cdef
val _ = abstraction_cache := Net.insert_term eq_absdef (v_rhs,ax)
(!abstraction_cache)
handle Net.INSERT =>
raise THM ("declare_absfuns: INSERT", 0, [th,u'_th,ax])
in (ax,thy) end
val _ = assert (v_rhs aconv rhs_of ax) "declare_absfuns: rhs mismatch"
val def = #1 (Drule.freeze_thaw ax)
val def_args = list_combination def (map (cterm_of thy) args)
in (transitive (abstract_rule v cv u'_th) (symmetric def_args),
def :: defs) end
| (t1$t2) =>
let val (ct1,ct2) = Thm.dest_comb ct
val (th1,defs1) = abstract thy ct1
val (th2,defs2) = abstract (theory_of_thm th1) ct2
in (combination th1 th2, defs1@defs2) end
val _ = if !trace_abs then warning (string_of_thm th) else ();
val (eqth,defs) = abstract (theory_of_thm th) (cprop_of th)
val ths = equal_elim eqth th ::
map (forall_intr_vars o strip_lambdas o object_eq) defs
in (theory_of_thm eqth, ths) end;
fun assume_absfuns th =
let val thy = theory_of_thm th
val cterm = cterm_of thy
fun abstract vs ct =
if lambda_free (term_of ct) then (reflexive ct, [])
else
case term_of ct of
Abs (_,T,u) =>
let val (cv,cta) = Thm.dest_abs NONE ct
val _ = assert_eta_free ct;
val v = (#1 o dest_Free o term_of) cv
val (u'_th,defs) = abstract (v::vs) cta
val cu' = crhs_of u'_th
val abs_v_u = Thm.cabs cv cu'
(*get the formal parameters: bound variables also present in the term*)
val args = filter (valid_name vs) (term_frees (term_of abs_v_u))
val crhs = list_cabs (map cterm args, abs_v_u)
(*Forms a lambda-abstraction over the formal parameters*)
val rhs = term_of crhs
val def = (*FIXME: can we also use the const-abstractions?*)
case List.find (fn ax => rhs aconv rhs_of ax andalso
Context.joinable (thy, theory_of_thm ax))
(Net.match_term (!abstraction_cache) rhs) of
SOME ax => ax
| NONE =>
let val Ts = map type_of args
val const_ty = Ts ---> (T --> typ_of (ctyp_of_term cu'))
val c = Free (gensym "abs_", const_ty)
val ax = assume (Thm.capply (cterm (equals const_ty $ c)) crhs)
val _ = abstraction_cache := Net.insert_term eq_absdef (rhs,ax)
(!abstraction_cache)
handle Net.INSERT =>
raise THM ("assume_absfuns: INSERT", 0, [th,u'_th,ax])
in ax end
val _ = assert (rhs aconv rhs_of def) "assume_absfuns: rhs mismatch"
val def_args = list_combination def (map cterm args)
in (transitive (abstract_rule v cv u'_th) (symmetric def_args),
def :: defs) end
| (t1$t2) =>
let val (ct1,ct2) = Thm.dest_comb ct
val (t1',defs1) = abstract vs ct1
val (t2',defs2) = abstract vs ct2
in (combination t1' t2', defs1@defs2) end
val (eqth,defs) = abstract [] (cprop_of th)
in equal_elim eqth th ::
map (forall_intr_vars o strip_lambdas o object_eq) defs
end;
(*cterms are used throughout for efficiency*)
val cTrueprop = Thm.cterm_of HOL.thy HOLogic.Trueprop;
(*cterm version of mk_cTrueprop*)
fun c_mkTrueprop A = Thm.capply cTrueprop A;
(*Given an abstraction over n variables, replace the bound variables by free
ones. Return the body, along with the list of free variables.*)
fun c_variant_abs_multi (ct0, vars) =
let val (cv,ct) = Thm.dest_abs NONE ct0
in c_variant_abs_multi (ct, cv::vars) end
handle CTERM _ => (ct0, rev vars);
(*Given the definition of a Skolem function, return a theorem to replace
an existential formula by a use of that function.
Example: "EX x. x : A & x ~: B ==> sko A B : A & sko A B ~: B" [.] *)
fun skolem_of_def def =
let val (c,rhs) = Drule.dest_equals (cprop_of (#1 (Drule.freeze_thaw def)))
val (ch, frees) = c_variant_abs_multi (rhs, [])
val (chilbert,cabs) = Thm.dest_comb ch
val {sign,t, ...} = rep_cterm chilbert
val T = case t of Const ("Hilbert_Choice.Eps", Type("fun",[_,T])) => T
| _ => raise THM ("skolem_of_def: expected Eps", 0, [def])
val cex = Thm.cterm_of sign (HOLogic.exists_const T)
val ex_tm = c_mkTrueprop (Thm.capply cex cabs)
and conc = c_mkTrueprop (Drule.beta_conv cabs (Drule.list_comb(c,frees)));
fun tacf [prem] = rewrite_goals_tac [def] THEN rtac (prem RS someI_ex) 1
in Goal.prove_raw [ex_tm] conc tacf
|> forall_intr_list frees
|> forall_elim_vars 0 (*Introduce Vars, but don't discharge defs.*)
|> Thm.varifyT
end;
(*Converts an Isabelle theorem (intro, elim or simp format) into nnf.*)
(*It now works for HOL too. *)
fun to_nnf th =
th |> transfer_to_Reconstruction
|> transform_elim |> zero_var_indexes |> Drule.freeze_thaw |> #1
|> ObjectLogic.atomize_thm |> make_nnf;
(*The cache prevents repeated clausification of a theorem,
and also repeated declaration of Skolem functions*)
(* FIXME better use Termtab!? No, we MUST use theory data!!*)
val clause_cache = ref (Symtab.empty : (thm * thm list) Symtab.table)
(*Generate Skolem functions for a theorem supplied in nnf*)
fun skolem_of_nnf th =
map (skolem_of_def o assume o (cterm_of (theory_of_thm th))) (assume_skofuns th);
fun assert_lambda_free ths = assert (forall (lambda_free o prop_of) ths);
fun assume_abstract th =
if lambda_free (prop_of th) then [th]
else th |> eta_conversion_rule |> assume_absfuns
|> tap (fn ths => assert_lambda_free ths "assume_abstract: lambdas")
(*Replace lambdas by assumed function definitions in the theorems*)
fun assume_abstract_list ths =
if abstract_lambdas then List.concat (map assume_abstract ths)
else map eta_conversion_rule ths;
(*Replace lambdas by declared function definitions in the theorems*)
fun declare_abstract' (thy, []) = (thy, [])
| declare_abstract' (thy, th::ths) =
let val (thy', th_defs) =
if lambda_free (prop_of th) then (thy, [th])
else
th |> zero_var_indexes |> Drule.freeze_thaw |> #1
|> eta_conversion_rule |> transfer thy |> declare_absfuns
val _ = assert_lambda_free th_defs "declare_abstract: lambdas"
val (thy'', ths') = declare_abstract' (thy', ths)
in (thy'', th_defs @ ths') end;
(*FIXME DELETE if we decide to switch to abstractions*)
fun declare_abstract (thy, ths) =
if abstract_lambdas then declare_abstract' (thy, ths)
else (thy, map eta_conversion_rule ths);
(*Skolemize a named theorem, with Skolem functions as additional premises.*)
(*also works for HOL*)
fun skolem_thm th =
let val nnfth = to_nnf th
in Meson.make_cnf (skolem_of_nnf nnfth) nnfth
|> assume_abstract_list |> Meson.finish_cnf |> rm_redundant_cls
end
handle THM _ => [];
(*Declare Skolem functions for a theorem, supplied in nnf and with its name.
It returns a modified theory, unless skolemization fails.*)
fun skolem thy (name,th) =
let val cname = (case name of "" => gensym "" | s => Sign.base_name s)
val _ = Output.debug ("skolemizing " ^ name ^ ": ")
in Option.map
(fn nnfth =>
let val (thy',defs) = declare_skofuns cname nnfth thy
val cnfs = Meson.make_cnf (map skolem_of_def defs) nnfth
val (thy'',cnfs') = declare_abstract (thy',cnfs)
in (thy'', rm_redundant_cls (Meson.finish_cnf cnfs'))
end)
(SOME (to_nnf th) handle THM _ => NONE)
end;
(*Populate the clause cache using the supplied theorem. Return the clausal form
and modified theory.*)
fun skolem_cache_thm (name,th) thy =
case Symtab.lookup (!clause_cache) name of
NONE =>
(case skolem thy (name, Thm.transfer thy th) of
NONE => ([th],thy)
| SOME (thy',cls) =>
let val cls = map Drule.local_standard cls
in
if null cls then warning ("skolem_cache: empty clause set for " ^ name)
else ();
change clause_cache (Symtab.update (name, (th, cls)));
(cls,thy')
end)
| SOME (th',cls) =>
if eq_thm(th,th') then (cls,thy)
else (Output.debug ("skolem_cache: Ignoring variant of theorem " ^ name);
Output.debug (string_of_thm th);
Output.debug (string_of_thm th');
([th],thy));
(*Exported function to convert Isabelle theorems into axiom clauses*)
fun cnf_axiom (name,th) =
case name of
"" => skolem_thm th (*no name, so can't cache*)
| s => case Symtab.lookup (!clause_cache) s of
NONE =>
let val cls = map Drule.local_standard (skolem_thm th)
in change clause_cache (Symtab.update (s, (th, cls))); cls end
| SOME(th',cls) =>
if eq_thm(th,th') then cls
else (Output.debug ("cnf_axiom: duplicate or variant of theorem " ^ name);
Output.debug (string_of_thm th);
Output.debug (string_of_thm th');
cls);
fun pairname th = (Thm.name_of_thm th, th);
fun meta_cnf_axiom th =
map Meson.make_meta_clause (cnf_axiom (pairname th));
(**** Extract and Clausify theorems from a theory's claset and simpset ****)
(*Preserve the name of "th" after the transformation "f"*)
fun preserve_name f th = Thm.name_thm (Thm.name_of_thm th, f th);
fun rules_of_claset cs =
let val {safeIs,safeEs,hazIs,hazEs,...} = rep_cs cs
val intros = safeIs @ hazIs
val elims = map Classical.classical_rule (safeEs @ hazEs)
in
Output.debug ("rules_of_claset intros: " ^ Int.toString(length intros) ^
" elims: " ^ Int.toString(length elims));
map pairname (intros @ elims)
end;
fun rules_of_simpset ss =
let val ({rules,...}, _) = rep_ss ss
val simps = Net.entries rules
in
Output.debug ("rules_of_simpset: " ^ Int.toString(length simps));
map (fn r => (#name r, #thm r)) simps
end;
fun claset_rules_of_thy thy = rules_of_claset (claset_of thy);
fun simpset_rules_of_thy thy = rules_of_simpset (simpset_of thy);
fun atpset_rules_of_thy thy = map pairname (ResAtpSet.atp_rules_of_thy thy);
fun claset_rules_of_ctxt ctxt = rules_of_claset (local_claset_of ctxt);
fun simpset_rules_of_ctxt ctxt = rules_of_simpset (local_simpset_of ctxt);
fun atpset_rules_of_ctxt ctxt = map pairname (ResAtpSet.atp_rules_of_ctxt ctxt);
(**** Translate a set of classical/simplifier rules into CNF (still as type "thm") ****)
(* classical rules: works for both FOL and HOL *)
fun cnf_rules [] err_list = ([],err_list)
| cnf_rules ((name,th) :: ths) err_list =
let val (ts,es) = cnf_rules ths err_list
in (cnf_axiom (name,th) :: ts,es) handle _ => (ts, (th::es)) end;
fun pair_name_cls k (n, []) = []
| pair_name_cls k (n, cls::clss) = (cls, (n,k)) :: pair_name_cls (k+1) (n, clss)
fun cnf_rules_pairs_aux pairs [] = pairs
| cnf_rules_pairs_aux pairs ((name,th)::ths) =
let val pairs' = (pair_name_cls 0 (name, cnf_axiom(name,th))) @ pairs
handle THM _ => pairs | ResClause.CLAUSE _ => pairs
| ResHolClause.LAM2COMB _ => pairs
in cnf_rules_pairs_aux pairs' ths end;
val cnf_rules_pairs = cnf_rules_pairs_aux [];
(**** Convert all theorems of a claset/simpset into clauses (ResClause.clause, or ResHolClause.clause) ****)
(*Setup function: takes a theory and installs ALL known theorems into the clause cache*)
fun skolem_cache (name,th) thy =
let val prop = Thm.prop_of th
in
if lambda_free prop orelse monomorphic prop
then thy (*monomorphic theorems can be Skolemized on demand*)
else #2 (skolem_cache_thm (name,th) thy)
end;
fun clause_cache_setup thy = fold skolem_cache (PureThy.all_thms_of thy) thy;
(*** meson proof methods ***)
fun cnf_rules_of_ths ths = List.concat (#1 (cnf_rules (map pairname ths) []));
fun meson_meth ths ctxt =
Method.SIMPLE_METHOD' HEADGOAL
(CHANGED_PROP o Meson.meson_claset_tac (cnf_rules_of_ths ths) (local_claset_of ctxt));
val meson_method_setup =
Method.add_methods
[("meson", Method.thms_ctxt_args meson_meth,
"MESON resolution proof procedure")];
(*** The Skolemization attribute ***)
fun conj2_rule (th1,th2) = conjI OF [th1,th2];
(*Conjoin a list of theorems to form a single theorem*)
fun conj_rule [] = TrueI
| conj_rule ths = foldr1 conj2_rule ths;
fun skolem_attr (Context.Theory thy, th) =
let val name = Thm.name_of_thm th
val (cls, thy') = skolem_cache_thm (name, th) thy
in (Context.Theory thy', conj_rule cls) end
| skolem_attr (context, th) = (context, conj_rule (skolem_thm th));
val setup_attrs = Attrib.add_attributes
[("skolem", Attrib.no_args skolem_attr, "skolemization of a theorem")];
val setup = clause_cache_setup #> setup_attrs;
end;