--- a/src/HOL/Tools/res_hol_clause.ML Wed Mar 04 10:43:39 2009 +0100
+++ b/src/HOL/Tools/res_hol_clause.ML Wed Mar 04 10:45:52 2009 +0100
@@ -1,4 +1,4 @@
-(* ID: $Id$
+(*
Author: Jia Meng, NICTA
FOL clauses translated from HOL formulae.
@@ -13,8 +13,8 @@
val comb_C: thm
val comb_S: thm
datatype type_level = T_FULL | T_CONST
- val typ_level: type_level ref
- val minimize_applies: bool ref
+ val typ_level: type_level
+ val minimize_applies: bool
type axiom_name = string
type polarity = bool
type clause_id = int
@@ -53,22 +53,18 @@
(*The different translations of types*)
datatype type_level = T_FULL | T_CONST;
-val typ_level = ref T_CONST;
+val typ_level = T_CONST;
(*If true, each function will be directly applied to as many arguments as possible, avoiding
use of the "apply" operator. Use of hBOOL is also minimized.*)
-val minimize_applies = ref true;
-
-val const_min_arity = ref (Symtab.empty : int Symtab.table);
+val minimize_applies = true;
-val const_needs_hBOOL = ref (Symtab.empty : bool Symtab.table);
-
-fun min_arity_of c = getOpt (Symtab.lookup(!const_min_arity) c, 0);
+fun min_arity_of const_min_arity c = getOpt (Symtab.lookup const_min_arity c, 0);
(*True if the constant ever appears outside of the top-level position in literals.
If false, the constant always receives all of its arguments and is used as a predicate.*)
-fun needs_hBOOL c = not (!minimize_applies) orelse
- getOpt (Symtab.lookup(!const_needs_hBOOL) c, false);
+fun needs_hBOOL const_needs_hBOOL c = not minimize_applies orelse
+ getOpt (Symtab.lookup const_needs_hBOOL c, false);
(******************************************************)
@@ -110,67 +106,68 @@
fun isTaut (Clause {literals,...}) = exists isTrue literals;
-fun type_of (Type (a, Ts)) =
- let val (folTypes,ts) = types_of Ts
- in (RC.Comp(RC.make_fixed_type_const a, folTypes), ts) end
- | type_of (tp as (TFree(a,s))) =
+fun type_of dfg (Type (a, Ts)) =
+ let val (folTypes,ts) = types_of dfg Ts
+ in (RC.Comp(RC.make_fixed_type_const dfg a, folTypes), ts) end
+ | type_of dfg (tp as (TFree(a,s))) =
(RC.AtomF (RC.make_fixed_type_var a), [tp])
- | type_of (tp as (TVar(v,s))) =
+ | type_of dfg (tp as (TVar(v,s))) =
(RC.AtomV (RC.make_schematic_type_var v), [tp])
-and types_of Ts =
- let val (folTyps,ts) = ListPair.unzip (map type_of Ts)
+and types_of dfg Ts =
+ let val (folTyps,ts) = ListPair.unzip (map (type_of dfg) Ts)
in (folTyps, RC.union_all ts) end;
(* same as above, but no gathering of sort information *)
-fun simp_type_of (Type (a, Ts)) =
- RC.Comp(RC.make_fixed_type_const a, map simp_type_of Ts)
- | simp_type_of (TFree (a,s)) = RC.AtomF(RC.make_fixed_type_var a)
- | simp_type_of (TVar (v,s)) = RC.AtomV(RC.make_schematic_type_var v);
+fun simp_type_of dfg (Type (a, Ts)) =
+ RC.Comp(RC.make_fixed_type_const dfg a, map (simp_type_of dfg) Ts)
+ | simp_type_of dfg (TFree (a,s)) = RC.AtomF(RC.make_fixed_type_var a)
+ | simp_type_of dfg (TVar (v,s)) = RC.AtomV(RC.make_schematic_type_var v);
-fun const_type_of thy (c,t) =
- let val (tp,ts) = type_of t
- in (tp, ts, map simp_type_of (Sign.const_typargs thy (c,t))) end;
+fun const_type_of dfg thy (c,t) =
+ let val (tp,ts) = type_of dfg t
+ in (tp, ts, map (simp_type_of dfg) (Sign.const_typargs thy (c,t))) end;
(* convert a Term.term (with combinators) into a combterm, also accummulate sort info *)
-fun combterm_of thy (Const(c,t)) =
- let val (tp,ts,tvar_list) = const_type_of thy (c,t)
- val c' = CombConst(RC.make_fixed_const c, tp, tvar_list)
+fun combterm_of dfg thy (Const(c,t)) =
+ let val (tp,ts,tvar_list) = const_type_of dfg thy (c,t)
+ val c' = CombConst(RC.make_fixed_const dfg c, tp, tvar_list)
in (c',ts) end
- | combterm_of thy (Free(v,t)) =
- let val (tp,ts) = type_of t
+ | combterm_of dfg thy (Free(v,t)) =
+ let val (tp,ts) = type_of dfg t
val v' = CombConst(RC.make_fixed_var v, tp, [])
in (v',ts) end
- | combterm_of thy (Var(v,t)) =
- let val (tp,ts) = type_of t
+ | combterm_of dfg thy (Var(v,t)) =
+ let val (tp,ts) = type_of dfg t
val v' = CombVar(RC.make_schematic_var v,tp)
in (v',ts) end
- | combterm_of thy (P $ Q) =
- let val (P',tsP) = combterm_of thy P
- val (Q',tsQ) = combterm_of thy Q
+ | combterm_of dfg thy (P $ Q) =
+ let val (P',tsP) = combterm_of dfg thy P
+ val (Q',tsQ) = combterm_of dfg thy Q
in (CombApp(P',Q'), tsP union tsQ) end
- | combterm_of thy (t as Abs _) = raise RC.CLAUSE("HOL CLAUSE",t);
+ | combterm_of _ thy (t as Abs _) = raise RC.CLAUSE("HOL CLAUSE",t);
-fun predicate_of thy ((Const("Not",_) $ P), polarity) = predicate_of thy (P, not polarity)
- | predicate_of thy (t,polarity) = (combterm_of thy (Envir.eta_contract t), polarity);
+fun predicate_of dfg thy ((Const("Not",_) $ P), polarity) = predicate_of dfg thy (P, not polarity)
+ | predicate_of dfg thy (t,polarity) = (combterm_of dfg thy (Envir.eta_contract t), polarity);
-fun literals_of_term1 thy args (Const("Trueprop",_) $ P) = literals_of_term1 thy args P
- | literals_of_term1 thy args (Const("op |",_) $ P $ Q) =
- literals_of_term1 thy (literals_of_term1 thy args P) Q
- | literals_of_term1 thy (lits,ts) P =
- let val ((pred,ts'),pol) = predicate_of thy (P,true)
+fun literals_of_term1 dfg thy args (Const("Trueprop",_) $ P) = literals_of_term1 dfg thy args P
+ | literals_of_term1 dfg thy args (Const("op |",_) $ P $ Q) =
+ literals_of_term1 dfg thy (literals_of_term1 dfg thy args P) Q
+ | literals_of_term1 dfg thy (lits,ts) P =
+ let val ((pred,ts'),pol) = predicate_of dfg thy (P,true)
in
(Literal(pol,pred)::lits, ts union ts')
end;
-fun literals_of_term thy P = literals_of_term1 thy ([],[]) P;
+fun literals_of_term_dfg dfg thy P = literals_of_term1 dfg thy ([],[]) P;
+val literals_of_term = literals_of_term_dfg false;
(* Problem too trivial for resolution (empty clause) *)
exception TOO_TRIVIAL;
(* making axiom and conjecture clauses *)
-fun make_clause thy (clause_id,axiom_name,kind,th) =
- let val (lits,ctypes_sorts) = literals_of_term thy (prop_of th)
+fun make_clause dfg thy (clause_id,axiom_name,kind,th) =
+ let val (lits,ctypes_sorts) = literals_of_term_dfg dfg thy (prop_of th)
in
if forall isFalse lits
then raise TOO_TRIVIAL
@@ -180,20 +177,20 @@
end;
-fun add_axiom_clause thy ((th,(name,id)), pairs) =
- let val cls = make_clause thy (id, name, RC.Axiom, th)
+fun add_axiom_clause dfg thy ((th,(name,id)), pairs) =
+ let val cls = make_clause dfg thy (id, name, RC.Axiom, th)
in
if isTaut cls then pairs else (name,cls)::pairs
end;
-fun make_axiom_clauses thy = foldl (add_axiom_clause thy) [];
+fun make_axiom_clauses dfg thy = List.foldl (add_axiom_clause dfg thy) [];
-fun make_conjecture_clauses_aux _ _ [] = []
- | make_conjecture_clauses_aux thy n (th::ths) =
- make_clause thy (n,"conjecture", RC.Conjecture, th) ::
- make_conjecture_clauses_aux thy (n+1) ths;
+fun make_conjecture_clauses_aux dfg _ _ [] = []
+ | make_conjecture_clauses_aux dfg thy n (th::ths) =
+ make_clause dfg thy (n,"conjecture", RC.Conjecture, th) ::
+ make_conjecture_clauses_aux dfg thy (n+1) ths;
-fun make_conjecture_clauses thy = make_conjecture_clauses_aux thy 0;
+fun make_conjecture_clauses dfg thy = make_conjecture_clauses_aux dfg thy 0;
(**********************************************************************)
@@ -218,11 +215,11 @@
val type_wrapper = "ti";
-fun head_needs_hBOOL (CombConst(c,_,_)) = needs_hBOOL c
- | head_needs_hBOOL _ = true;
+fun head_needs_hBOOL const_needs_hBOOL (CombConst(c,_,_)) = needs_hBOOL const_needs_hBOOL c
+ | head_needs_hBOOL const_needs_hBOOL _ = true;
fun wrap_type (s, tp) =
- if !typ_level=T_FULL then
+ if typ_level=T_FULL then
type_wrapper ^ RC.paren_pack [s, RC.string_of_fol_type tp]
else s;
@@ -235,43 +232,43 @@
(*Apply an operator to the argument strings, using either the "apply" operator or
direct function application.*)
-fun string_of_applic (CombConst(c,tp,tvars), args) =
+fun string_of_applic cma (CombConst(c,tp,tvars), args) =
let val c = if c = "equal" then "c_fequal" else c
- val nargs = min_arity_of c
+ val nargs = min_arity_of cma c
val args1 = List.take(args, nargs)
handle Subscript => error ("string_of_applic: " ^ c ^ " has arity " ^
Int.toString nargs ^ " but is applied to " ^
space_implode ", " args)
val args2 = List.drop(args, nargs)
- val targs = if !typ_level = T_CONST then map RC.string_of_fol_type tvars
+ val targs = if typ_level = T_CONST then map RC.string_of_fol_type tvars
else []
in
string_apply (c ^ RC.paren_pack (args1@targs), args2)
end
- | string_of_applic (CombVar(v,tp), args) = string_apply (v, args)
- | string_of_applic _ = error "string_of_applic";
+ | string_of_applic cma (CombVar(v,tp), args) = string_apply (v, args)
+ | string_of_applic _ _ = error "string_of_applic";
-fun wrap_type_if (head, s, tp) = if head_needs_hBOOL head then wrap_type (s, tp) else s;
+fun wrap_type_if cnh (head, s, tp) = if head_needs_hBOOL cnh head then wrap_type (s, tp) else s;
-fun string_of_combterm t =
+fun string_of_combterm cma cnh t =
let val (head, args) = strip_comb t
- in wrap_type_if (head,
- string_of_applic (head, map string_of_combterm args),
+ in wrap_type_if cnh (head,
+ string_of_applic cma (head, map (string_of_combterm cma cnh) args),
type_of_combterm t)
end;
(*Boolean-valued terms are here converted to literals.*)
-fun boolify t = "hBOOL" ^ RC.paren_pack [string_of_combterm t];
+fun boolify cma cnh t = "hBOOL" ^ RC.paren_pack [string_of_combterm cma cnh t];
-fun string_of_predicate t =
+fun string_of_predicate cma cnh t =
case t of
(CombApp(CombApp(CombConst("equal",_,_), t1), t2)) =>
(*DFG only: new TPTP prefers infix equality*)
- ("equal" ^ RC.paren_pack [string_of_combterm t1, string_of_combterm t2])
+ ("equal" ^ RC.paren_pack [string_of_combterm cma cnh t1, string_of_combterm cma cnh t2])
| _ =>
case #1 (strip_comb t) of
- CombConst(c,_,_) => if needs_hBOOL c then boolify t else string_of_combterm t
- | _ => boolify t;
+ CombConst(c,_,_) => if needs_hBOOL cnh c then boolify cma cnh t else string_of_combterm cma cnh t
+ | _ => boolify cma cnh t;
fun string_of_clausename (cls_id,ax_name) =
RC.clause_prefix ^ RC.ascii_of ax_name ^ "_" ^ Int.toString cls_id;
@@ -282,23 +279,23 @@
(*** tptp format ***)
-fun tptp_of_equality pol (t1,t2) =
+fun tptp_of_equality cma cnh pol (t1,t2) =
let val eqop = if pol then " = " else " != "
- in string_of_combterm t1 ^ eqop ^ string_of_combterm t2 end;
+ in string_of_combterm cma cnh t1 ^ eqop ^ string_of_combterm cma cnh t2 end;
-fun tptp_literal (Literal(pol, CombApp(CombApp(CombConst("equal",_,_), t1), t2))) =
- tptp_of_equality pol (t1,t2)
- | tptp_literal (Literal(pol,pred)) =
- RC.tptp_sign pol (string_of_predicate pred);
+fun tptp_literal cma cnh (Literal(pol, CombApp(CombApp(CombConst("equal",_,_), t1), t2))) =
+ tptp_of_equality cma cnh pol (t1,t2)
+ | tptp_literal cma cnh (Literal(pol,pred)) =
+ RC.tptp_sign pol (string_of_predicate cma cnh pred);
(*Given a clause, returns its literals paired with a list of literals concerning TFrees;
the latter should only occur in conjecture clauses.*)
-fun tptp_type_lits pos (Clause{literals, ctypes_sorts, ...}) =
- (map tptp_literal literals,
+fun tptp_type_lits cma cnh pos (Clause{literals, ctypes_sorts, ...}) =
+ (map (tptp_literal cma cnh) literals,
map (RC.tptp_of_typeLit pos) (RC.add_typs ctypes_sorts));
-fun clause2tptp (cls as Clause{axiom_name,clause_id,kind,ctypes_sorts,...}) =
- let val (lits,tylits) = tptp_type_lits (kind = RC.Conjecture) cls
+fun clause2tptp cma cnh (cls as Clause{axiom_name,clause_id,kind,ctypes_sorts,...}) =
+ let val (lits,tylits) = tptp_type_lits cma cnh (kind = RC.Conjecture) cls
in
(RC.gen_tptp_cls(clause_id,axiom_name,kind,lits,tylits), tylits)
end;
@@ -306,10 +303,10 @@
(*** dfg format ***)
-fun dfg_literal (Literal(pol,pred)) = RC.dfg_sign pol (string_of_predicate pred);
+fun dfg_literal cma cnh (Literal(pol,pred)) = RC.dfg_sign pol (string_of_predicate cma cnh pred);
-fun dfg_type_lits pos (Clause{literals, ctypes_sorts, ...}) =
- (map dfg_literal literals,
+fun dfg_type_lits cma cnh pos (Clause{literals, ctypes_sorts, ...}) =
+ (map (dfg_literal cma cnh) literals,
map (RC.dfg_of_typeLit pos) (RC.add_typs ctypes_sorts));
fun get_uvars (CombConst _) vars = vars
@@ -320,8 +317,8 @@
fun dfg_vars (Clause {literals,...}) = RC.union_all (map get_uvars_l literals);
-fun clause2dfg (cls as Clause{axiom_name,clause_id,kind,ctypes_sorts,...}) =
- let val (lits,tylits) = dfg_type_lits (kind = RC.Conjecture) cls
+fun clause2dfg cma cnh (cls as Clause{axiom_name,clause_id,kind,ctypes_sorts,...}) =
+ let val (lits,tylits) = dfg_type_lits cma cnh (kind = RC.Conjecture) cls
val vars = dfg_vars cls
val tvars = RC.get_tvar_strs ctypes_sorts
in
@@ -331,47 +328,47 @@
(** For DFG format: accumulate function and predicate declarations **)
-fun addtypes tvars tab = foldl RC.add_foltype_funcs tab tvars;
+fun addtypes tvars tab = List.foldl RC.add_foltype_funcs tab tvars;
-fun add_decls (CombConst(c,tp,tvars), (funcs,preds)) =
+fun add_decls cma cnh (CombConst(c,tp,tvars), (funcs,preds)) =
if c = "equal" then (addtypes tvars funcs, preds)
else
- let val arity = min_arity_of c
- val ntys = if !typ_level = T_CONST then length tvars else 0
+ let val arity = min_arity_of cma c
+ val ntys = if typ_level = T_CONST then length tvars else 0
val addit = Symtab.update(c, arity+ntys)
in
- if needs_hBOOL c then (addtypes tvars (addit funcs), preds)
+ if needs_hBOOL cnh c then (addtypes tvars (addit funcs), preds)
else (addtypes tvars funcs, addit preds)
end
- | add_decls (CombVar(_,ctp), (funcs,preds)) =
+ | add_decls _ _ (CombVar(_,ctp), (funcs,preds)) =
(RC.add_foltype_funcs (ctp,funcs), preds)
- | add_decls (CombApp(P,Q),decls) = add_decls(P,add_decls (Q,decls));
+ | add_decls cma cnh (CombApp(P,Q),decls) = add_decls cma cnh (P,add_decls cma cnh (Q,decls));
-fun add_literal_decls (Literal(_,c), decls) = add_decls (c,decls);
+fun add_literal_decls cma cnh (Literal(_,c), decls) = add_decls cma cnh (c,decls);
-fun add_clause_decls (Clause {literals, ...}, decls) =
- foldl add_literal_decls decls literals
+fun add_clause_decls cma cnh (Clause {literals, ...}, decls) =
+ List.foldl (add_literal_decls cma cnh) decls literals
handle Symtab.DUP a => error ("function " ^ a ^ " has multiple arities")
-fun decls_of_clauses clauses arity_clauses =
+fun decls_of_clauses cma cnh clauses arity_clauses =
let val init_functab = Symtab.update (type_wrapper,2) (Symtab.update ("hAPP",2) RC.init_functab)
val init_predtab = Symtab.update ("hBOOL",1) Symtab.empty
- val (functab,predtab) = (foldl add_clause_decls (init_functab, init_predtab) clauses)
+ val (functab,predtab) = (List.foldl (add_clause_decls cma cnh) (init_functab, init_predtab) clauses)
in
- (Symtab.dest (foldl RC.add_arityClause_funcs functab arity_clauses),
+ (Symtab.dest (List.foldl RC.add_arityClause_funcs functab arity_clauses),
Symtab.dest predtab)
end;
fun add_clause_preds (Clause {ctypes_sorts, ...}, preds) =
- foldl RC.add_type_sort_preds preds ctypes_sorts
+ List.foldl RC.add_type_sort_preds preds ctypes_sorts
handle Symtab.DUP a => error ("predicate " ^ a ^ " has multiple arities")
(*Higher-order clauses have only the predicates hBOOL and type classes.*)
fun preds_of_clauses clauses clsrel_clauses arity_clauses =
Symtab.dest
- (foldl RC.add_classrelClause_preds
- (foldl RC.add_arityClause_preds
- (foldl add_clause_preds Symtab.empty clauses)
+ (List.foldl RC.add_classrelClause_preds
+ (List.foldl RC.add_arityClause_preds
+ (List.foldl add_clause_preds Symtab.empty clauses)
arity_clauses)
clsrel_clauses)
@@ -393,20 +390,20 @@
fun count_literal (Literal(_,t), ct) = count_combterm(t,ct);
-fun count_clause (Clause{literals,...}, ct) = foldl count_literal ct literals;
+fun count_clause (Clause{literals,...}, ct) = List.foldl count_literal ct literals;
fun count_user_clause user_lemmas (Clause{axiom_name,literals,...}, ct) =
- if axiom_name mem_string user_lemmas then foldl count_literal ct literals
+ if axiom_name mem_string user_lemmas then List.foldl count_literal ct literals
else ct;
fun cnf_helper_thms thy =
ResAxioms.cnf_rules_pairs thy o map ResAxioms.pairname
-fun get_helper_clauses thy isFO (conjectures, axclauses, user_lemmas) =
+fun get_helper_clauses dfg thy isFO (conjectures, axclauses, user_lemmas) =
if isFO then [] (*first-order*)
else
- let val ct0 = foldl count_clause init_counters conjectures
- val ct = foldl (count_user_clause user_lemmas) ct0 axclauses
+ let val ct0 = List.foldl count_clause init_counters conjectures
+ val ct = List.foldl (count_user_clause user_lemmas) ct0 axclauses
fun needed c = valOf (Symtab.lookup ct c) > 0
val IK = if needed "c_COMBI" orelse needed "c_COMBK"
then (Output.debug (fn () => "Include combinator I K"); cnf_helper_thms thy [comb_I,comb_K])
@@ -419,66 +416,67 @@
else []
val other = cnf_helper_thms thy [ext,fequal_imp_equal,equal_imp_fequal]
in
- map #2 (make_axiom_clauses thy (other @ IK @ BC @ S))
+ map #2 (make_axiom_clauses dfg thy (other @ IK @ BC @ S))
end;
(*Find the minimal arity of each function mentioned in the term. Also, note which uses
are not at top level, to see if hBOOL is needed.*)
-fun count_constants_term toplev t =
+fun count_constants_term toplev t (const_min_arity, const_needs_hBOOL) =
let val (head, args) = strip_comb t
val n = length args
- val _ = List.app (count_constants_term false) args
+ val (const_min_arity, const_needs_hBOOL) = fold (count_constants_term false) args (const_min_arity, const_needs_hBOOL)
in
case head of
CombConst (a,_,_) => (*predicate or function version of "equal"?*)
let val a = if a="equal" andalso not toplev then "c_fequal" else a
+ val const_min_arity = Symtab.map_default (a,n) (curry Int.min n) const_min_arity
in
- const_min_arity := Symtab.map_default (a,n) (curry Int.min n) (!const_min_arity);
- if toplev then ()
- else const_needs_hBOOL := Symtab.update (a,true) (!const_needs_hBOOL)
+ if toplev then (const_min_arity, const_needs_hBOOL)
+ else (const_min_arity, Symtab.update (a,true) (const_needs_hBOOL))
end
- | ts => ()
+ | ts => (const_min_arity, const_needs_hBOOL)
end;
(*A literal is a top-level term*)
-fun count_constants_lit (Literal (_,t)) = count_constants_term true t;
-
-fun count_constants_clause (Clause{literals,...}) = List.app count_constants_lit literals;
+fun count_constants_lit (Literal (_,t)) (const_min_arity, const_needs_hBOOL) =
+ count_constants_term true t (const_min_arity, const_needs_hBOOL);
-fun display_arity (c,n) =
+fun count_constants_clause (Clause{literals,...}) (const_min_arity, const_needs_hBOOL) =
+ fold count_constants_lit literals (const_min_arity, const_needs_hBOOL);
+
+fun display_arity const_needs_hBOOL (c,n) =
Output.debug (fn () => "Constant: " ^ c ^ " arity:\t" ^ Int.toString n ^
- (if needs_hBOOL c then " needs hBOOL" else ""));
+ (if needs_hBOOL const_needs_hBOOL c then " needs hBOOL" else ""));
fun count_constants (conjectures, axclauses, helper_clauses) =
- if !minimize_applies then
- (const_min_arity := Symtab.empty;
- const_needs_hBOOL := Symtab.empty;
- List.app count_constants_clause conjectures;
- List.app count_constants_clause axclauses;
- List.app count_constants_clause helper_clauses;
- List.app display_arity (Symtab.dest (!const_min_arity)))
- else ();
+ if minimize_applies then
+ let val (const_min_arity, const_needs_hBOOL) =
+ fold count_constants_clause conjectures (Symtab.empty, Symtab.empty)
+ |> fold count_constants_clause axclauses
+ |> fold count_constants_clause helper_clauses
+ val _ = List.app (display_arity const_needs_hBOOL) (Symtab.dest (const_min_arity))
+ in (const_min_arity, const_needs_hBOOL) end
+ else (Symtab.empty, Symtab.empty);
(* tptp format *)
(* write TPTP format to a single file *)
fun tptp_write_file thy isFO thms filename (ax_tuples,classrel_clauses,arity_clauses) user_lemmas =
let val _ = Output.debug (fn () => ("Preparing to write the TPTP file " ^ filename))
- val _ = RC.dfg_format := false
- val conjectures = make_conjecture_clauses thy thms
- val (clnames,axclauses) = ListPair.unzip (make_axiom_clauses thy ax_tuples)
- val helper_clauses = get_helper_clauses thy isFO (conjectures, axclauses, user_lemmas)
- val _ = count_constants (conjectures, axclauses, helper_clauses);
- val (tptp_clss,tfree_litss) = ListPair.unzip (map clause2tptp conjectures)
- val tfree_clss = map RC.tptp_tfree_clause (foldl (op union_string) [] tfree_litss)
+ val conjectures = make_conjecture_clauses false thy thms
+ val (clnames,axclauses) = ListPair.unzip (make_axiom_clauses false thy ax_tuples)
+ val helper_clauses = get_helper_clauses false thy isFO (conjectures, axclauses, user_lemmas)
+ val (const_min_arity, const_needs_hBOOL) = count_constants (conjectures, axclauses, helper_clauses);
+ val (tptp_clss,tfree_litss) = ListPair.unzip (map (clause2tptp const_min_arity const_needs_hBOOL) conjectures)
+ val tfree_clss = map RC.tptp_tfree_clause (List.foldl (op union_string) [] tfree_litss)
val out = TextIO.openOut filename
in
- List.app (curry TextIO.output out o #1 o clause2tptp) axclauses;
+ List.app (curry TextIO.output out o #1 o (clause2tptp const_min_arity const_needs_hBOOL)) axclauses;
RC.writeln_strs out tfree_clss;
RC.writeln_strs out tptp_clss;
List.app (curry TextIO.output out o RC.tptp_classrelClause) classrel_clauses;
List.app (curry TextIO.output out o RC.tptp_arity_clause) arity_clauses;
- List.app (curry TextIO.output out o #1 o clause2tptp) helper_clauses;
+ List.app (curry TextIO.output out o #1 o (clause2tptp const_min_arity const_needs_hBOOL)) helper_clauses;
TextIO.closeOut out;
clnames
end;
@@ -488,18 +486,17 @@
fun dfg_write_file thy isFO thms filename (ax_tuples,classrel_clauses,arity_clauses) user_lemmas =
let val _ = Output.debug (fn () => ("Preparing to write the DFG file " ^ filename))
- val _ = RC.dfg_format := true
- val conjectures = make_conjecture_clauses thy thms
- val (clnames,axclauses) = ListPair.unzip (make_axiom_clauses thy ax_tuples)
- val helper_clauses = get_helper_clauses thy isFO (conjectures, axclauses, user_lemmas)
- val _ = count_constants (conjectures, axclauses, helper_clauses);
- val (dfg_clss, tfree_litss) = ListPair.unzip (map clause2dfg conjectures)
+ val conjectures = make_conjecture_clauses true thy thms
+ val (clnames,axclauses) = ListPair.unzip (make_axiom_clauses true thy ax_tuples)
+ val helper_clauses = get_helper_clauses true thy isFO (conjectures, axclauses, user_lemmas)
+ val (const_min_arity, const_needs_hBOOL) = count_constants (conjectures, axclauses, helper_clauses);
+ val (dfg_clss, tfree_litss) = ListPair.unzip (map (clause2dfg const_min_arity const_needs_hBOOL) conjectures)
and probname = Path.implode (Path.base (Path.explode filename))
- val axstrs = map (#1 o clause2dfg) axclauses
+ val axstrs = map (#1 o (clause2dfg const_min_arity const_needs_hBOOL)) axclauses
val tfree_clss = map RC.dfg_tfree_clause (RC.union_all tfree_litss)
val out = TextIO.openOut filename
- val helper_clauses_strs = map (#1 o clause2dfg) helper_clauses
- val (funcs,cl_preds) = decls_of_clauses (helper_clauses @ conjectures @ axclauses) arity_clauses
+ val helper_clauses_strs = map (#1 o (clause2dfg const_min_arity const_needs_hBOOL)) helper_clauses
+ val (funcs,cl_preds) = decls_of_clauses const_min_arity const_needs_hBOOL (helper_clauses @ conjectures @ axclauses) arity_clauses
and ty_preds = preds_of_clauses axclauses classrel_clauses arity_clauses
in
TextIO.output (out, RC.string_of_start probname);