(* Title: HOL/Tools/Sledgehammer/metis_tactics.ML
Author: Kong W. Susanto and Lawrence C. Paulson, CU Computer Laboratory
Copyright Cambridge University 2007
HOL setup for the Metis prover.
*)
signature METIS_TACTICS =
sig
val trace: bool Unsynchronized.ref
val type_lits: bool Config.T
val metis_tac: Proof.context -> thm list -> int -> tactic
val metisF_tac: Proof.context -> thm list -> int -> tactic
val metisFT_tac: Proof.context -> thm list -> int -> tactic
val setup: theory -> theory
end
structure Metis_Tactics : METIS_TACTICS =
struct
structure SFC = Sledgehammer_FOL_Clause
structure SHC = Sledgehammer_HOL_Clause
structure SPR = Sledgehammer_Proof_Reconstruct
val trace = Unsynchronized.ref false;
fun trace_msg msg = if !trace then tracing (msg ()) else ();
val (type_lits, type_lits_setup) = Attrib.config_bool "metis_type_lits" true;
datatype mode = FO | HO | FT (* first-order, higher-order, fully-typed *)
(* ------------------------------------------------------------------------- *)
(* Useful Theorems *)
(* ------------------------------------------------------------------------- *)
val EXCLUDED_MIDDLE = @{lemma "P ==> ~ P ==> False" by (rule notE)}
val REFL_THM = incr_indexes 2 @{lemma "t ~= t ==> False" by simp}
val subst_em = @{lemma "s = t ==> P s ==> ~ P t ==> False" by simp}
val ssubst_em = @{lemma "s = t ==> P t ==> ~ P s ==> False" by simp}
(* ------------------------------------------------------------------------- *)
(* Useful Functions *)
(* ------------------------------------------------------------------------- *)
(* match untyped terms*)
fun untyped_aconv (Const(a,_)) (Const(b,_)) = (a=b)
| untyped_aconv (Free(a,_)) (Free(b,_)) = (a=b)
| untyped_aconv (Var((a,_),_)) (Var((b,_),_)) = (a=b) (*the index is ignored!*)
| untyped_aconv (Bound i) (Bound j) = (i=j)
| untyped_aconv (Abs(a,_,t)) (Abs(b,_,u)) = (a=b) andalso untyped_aconv t u
| untyped_aconv (t1$t2) (u1$u2) = untyped_aconv t1 u1 andalso untyped_aconv t2 u2
| untyped_aconv _ _ = false;
(* Finding the relative location of an untyped term within a list of terms *)
fun get_index lit =
let val lit = Envir.eta_contract lit
fun get n [] = raise Empty
| get n (x::xs) = if untyped_aconv lit (Envir.eta_contract (HOLogic.dest_Trueprop x))
then n else get (n+1) xs
in get 1 end;
(* ------------------------------------------------------------------------- *)
(* HOL to FOL (Isabelle to Metis) *)
(* ------------------------------------------------------------------------- *)
fun fn_isa_to_met "equal" = "="
| fn_isa_to_met x = x;
fun metis_lit b c args = (b, (c, args));
fun hol_type_to_fol (SFC.AtomV x) = Metis.Term.Var x
| hol_type_to_fol (SFC.AtomF x) = Metis.Term.Fn(x,[])
| hol_type_to_fol (SFC.Comp(tc,tps)) = Metis.Term.Fn(tc, map hol_type_to_fol tps);
(*These two functions insert type literals before the real literals. That is the
opposite order from TPTP linkup, but maybe OK.*)
fun hol_term_to_fol_FO tm =
case SHC.strip_comb tm of
(SHC.CombConst(c,_,tys), tms) =>
let val tyargs = map hol_type_to_fol tys
val args = map hol_term_to_fol_FO tms
in Metis.Term.Fn (c, tyargs @ args) end
| (SHC.CombVar(v,_), []) => Metis.Term.Var v
| _ => error "hol_term_to_fol_FO";
fun hol_term_to_fol_HO (SHC.CombVar (a, _)) = Metis.Term.Var a
| hol_term_to_fol_HO (SHC.CombConst (a, _, tylist)) =
Metis.Term.Fn (fn_isa_to_met a, map hol_type_to_fol tylist)
| hol_term_to_fol_HO (SHC.CombApp (tm1, tm2)) =
Metis.Term.Fn (".", map hol_term_to_fol_HO [tm1, tm2]);
(*The fully-typed translation, to avoid type errors*)
fun wrap_type (tm, ty) = Metis.Term.Fn("ti", [tm, hol_type_to_fol ty]);
fun hol_term_to_fol_FT (SHC.CombVar(a, ty)) =
wrap_type (Metis.Term.Var a, ty)
| hol_term_to_fol_FT (SHC.CombConst(a, ty, _)) =
wrap_type (Metis.Term.Fn(fn_isa_to_met a, []), ty)
| hol_term_to_fol_FT (tm as SHC.CombApp(tm1,tm2)) =
wrap_type (Metis.Term.Fn(".", map hol_term_to_fol_FT [tm1,tm2]),
SHC.type_of_combterm tm);
fun hol_literal_to_fol FO (SHC.Literal (pol, tm)) =
let val (SHC.CombConst(p,_,tys), tms) = SHC.strip_comb tm
val tylits = if p = "equal" then [] else map hol_type_to_fol tys
val lits = map hol_term_to_fol_FO tms
in metis_lit pol (fn_isa_to_met p) (tylits @ lits) end
| hol_literal_to_fol HO (SHC.Literal (pol, tm)) =
(case SHC.strip_comb tm of
(SHC.CombConst("equal",_,_), tms) =>
metis_lit pol "=" (map hol_term_to_fol_HO tms)
| _ => metis_lit pol "{}" [hol_term_to_fol_HO tm]) (*hBOOL*)
| hol_literal_to_fol FT (SHC.Literal (pol, tm)) =
(case SHC.strip_comb tm of
(SHC.CombConst("equal",_,_), tms) =>
metis_lit pol "=" (map hol_term_to_fol_FT tms)
| _ => metis_lit pol "{}" [hol_term_to_fol_FT tm]) (*hBOOL*);
fun literals_of_hol_thm thy mode t =
let val (lits, types_sorts) = SHC.literals_of_term thy t
in (map (hol_literal_to_fol mode) lits, types_sorts) end;
(*Sign should be "true" for conjecture type constraints, "false" for type lits in clauses.*)
fun metis_of_typeLit pos (SFC.LTVar (s,x)) = metis_lit pos s [Metis.Term.Var x]
| metis_of_typeLit pos (SFC.LTFree (s,x)) = metis_lit pos s [Metis.Term.Fn(x,[])];
fun default_sort _ (TVar _) = false
| default_sort ctxt (TFree (x, s)) = (s = the_default [] (Variable.def_sort ctxt (x, ~1)));
fun metis_of_tfree tf =
Metis.Thm.axiom (Metis.LiteralSet.singleton (metis_of_typeLit true tf));
fun hol_thm_to_fol is_conjecture ctxt mode th =
let val thy = ProofContext.theory_of ctxt
val (mlits, types_sorts) =
(literals_of_hol_thm thy mode o HOLogic.dest_Trueprop o prop_of) th
in
if is_conjecture then
(Metis.Thm.axiom (Metis.LiteralSet.fromList mlits), SFC.add_typs types_sorts)
else
let val tylits = SFC.add_typs
(filter (not o default_sort ctxt) types_sorts)
val mtylits = if Config.get ctxt type_lits
then map (metis_of_typeLit false) tylits else []
in
(Metis.Thm.axiom (Metis.LiteralSet.fromList(mtylits @ mlits)), [])
end
end;
(* ARITY CLAUSE *)
fun m_arity_cls (SFC.TConsLit (c,t,args)) =
metis_lit true (SFC.make_type_class c) [Metis.Term.Fn(t, map Metis.Term.Var args)]
| m_arity_cls (SFC.TVarLit (c,str)) =
metis_lit false (SFC.make_type_class c) [Metis.Term.Var str];
(*TrueI is returned as the Isabelle counterpart because there isn't any.*)
fun arity_cls (SFC.ArityClause{conclLit,premLits,...}) =
(TrueI,
Metis.Thm.axiom (Metis.LiteralSet.fromList (map m_arity_cls (conclLit :: premLits))));
(* CLASSREL CLAUSE *)
fun m_classrel_cls subclass superclass =
[metis_lit false subclass [Metis.Term.Var "T"], metis_lit true superclass [Metis.Term.Var "T"]];
fun classrel_cls (SFC.ClassrelClause {subclass, superclass, ...}) =
(TrueI, Metis.Thm.axiom (Metis.LiteralSet.fromList (m_classrel_cls subclass superclass)));
(* ------------------------------------------------------------------------- *)
(* FOL to HOL (Metis to Isabelle) *)
(* ------------------------------------------------------------------------- *)
datatype term_or_type = Term of Term.term | Type of Term.typ;
fun terms_of [] = []
| terms_of (Term t :: tts) = t :: terms_of tts
| terms_of (Type _ :: tts) = terms_of tts;
fun types_of [] = []
| types_of (Term (Term.Var ((a,idx), _)) :: tts) =
if String.isPrefix "_" a then
(*Variable generated by Metis, which might have been a type variable.*)
TVar (("'" ^ a, idx), HOLogic.typeS) :: types_of tts
else types_of tts
| types_of (Term _ :: tts) = types_of tts
| types_of (Type T :: tts) = T :: types_of tts;
fun apply_list rator nargs rands =
let val trands = terms_of rands
in if length trands = nargs then Term (list_comb(rator, trands))
else error
("apply_list: wrong number of arguments: " ^ Syntax.string_of_term_global Pure.thy rator ^
" expected " ^ Int.toString nargs ^
" received " ^ commas (map (Syntax.string_of_term_global Pure.thy) trands))
end;
fun infer_types ctxt =
Syntax.check_terms (ProofContext.set_mode ProofContext.mode_pattern ctxt);
(*We use 1 rather than 0 because variable references in clauses may otherwise conflict
with variable constraints in the goal...at least, type inference often fails otherwise.
SEE ALSO axiom_inf below.*)
fun mk_var (w,T) = Term.Var((w,1), T);
(*include the default sort, if available*)
fun mk_tfree ctxt w =
let val ww = "'" ^ w
in TFree(ww, the_default HOLogic.typeS (Variable.def_sort ctxt (ww, ~1))) end;
(*Remove the "apply" operator from an HO term*)
fun strip_happ args (Metis.Term.Fn(".",[t,u])) = strip_happ (u::args) t
| strip_happ args x = (x, args);
fun fol_type_to_isa _ (Metis.Term.Var v) =
(case SPR.strip_prefix SFC.tvar_prefix v of
SOME w => SPR.make_tvar w
| NONE => SPR.make_tvar v)
| fol_type_to_isa ctxt (Metis.Term.Fn(x, tys)) =
(case SPR.strip_prefix SFC.tconst_prefix x of
SOME tc => Term.Type (SPR.invert_type_const tc, map (fol_type_to_isa ctxt) tys)
| NONE =>
case SPR.strip_prefix SFC.tfree_prefix x of
SOME tf => mk_tfree ctxt tf
| NONE => error ("fol_type_to_isa: " ^ x));
(*Maps metis terms to isabelle terms*)
fun fol_term_to_hol_RAW ctxt fol_tm =
let val thy = ProofContext.theory_of ctxt
val _ = trace_msg (fn () => "fol_term_to_hol: " ^ Metis.Term.toString fol_tm)
fun tm_to_tt (Metis.Term.Var v) =
(case SPR.strip_prefix SFC.tvar_prefix v of
SOME w => Type (SPR.make_tvar w)
| NONE =>
case SPR.strip_prefix SFC.schematic_var_prefix v of
SOME w => Term (mk_var (w, HOLogic.typeT))
| NONE => Term (mk_var (v, HOLogic.typeT)) )
(*Var from Metis with a name like _nnn; possibly a type variable*)
| tm_to_tt (Metis.Term.Fn ("{}", [arg])) = tm_to_tt arg (*hBOOL*)
| tm_to_tt (t as Metis.Term.Fn (".",_)) =
let val (rator,rands) = strip_happ [] t
in case rator of
Metis.Term.Fn(fname,ts) => applic_to_tt (fname, ts @ rands)
| _ => case tm_to_tt rator of
Term t => Term (list_comb(t, terms_of (map tm_to_tt rands)))
| _ => error "tm_to_tt: HO application"
end
| tm_to_tt (Metis.Term.Fn (fname, args)) = applic_to_tt (fname,args)
and applic_to_tt ("=",ts) =
Term (list_comb(Const ("op =", HOLogic.typeT), terms_of (map tm_to_tt ts)))
| applic_to_tt (a,ts) =
case SPR.strip_prefix SFC.const_prefix a of
SOME b =>
let val c = SPR.invert_const b
val ntypes = SPR.num_typargs thy c
val nterms = length ts - ntypes
val tts = map tm_to_tt ts
val tys = types_of (List.take(tts,ntypes))
val ntyargs = SPR.num_typargs thy c
in if length tys = ntyargs then
apply_list (Const (c, dummyT)) nterms (List.drop(tts,ntypes))
else error ("Constant " ^ c ^ " expects " ^ Int.toString ntyargs ^
" but gets " ^ Int.toString (length tys) ^
" type arguments\n" ^
cat_lines (map (Syntax.string_of_typ ctxt) tys) ^
" the terms are \n" ^
cat_lines (map (Syntax.string_of_term ctxt) (terms_of tts)))
end
| NONE => (*Not a constant. Is it a type constructor?*)
case SPR.strip_prefix SFC.tconst_prefix a of
SOME b =>
Type (Term.Type (SPR.invert_type_const b, types_of (map tm_to_tt ts)))
| NONE => (*Maybe a TFree. Should then check that ts=[].*)
case SPR.strip_prefix SFC.tfree_prefix a of
SOME b => Type (mk_tfree ctxt b)
| NONE => (*a fixed variable? They are Skolem functions.*)
case SPR.strip_prefix SFC.fixed_var_prefix a of
SOME b =>
let val opr = Term.Free(b, HOLogic.typeT)
in apply_list opr (length ts) (map tm_to_tt ts) end
| NONE => error ("unexpected metis function: " ^ a)
in case tm_to_tt fol_tm of Term t => t | _ => error "fol_tm_to_tt: Term expected" end;
(*Maps fully-typed metis terms to isabelle terms*)
fun fol_term_to_hol_FT ctxt fol_tm =
let val _ = trace_msg (fn () => "fol_term_to_hol_FT: " ^ Metis.Term.toString fol_tm)
fun cvt (Metis.Term.Fn ("ti", [Metis.Term.Var v, _])) =
(case SPR.strip_prefix SFC.schematic_var_prefix v of
SOME w => mk_var(w, dummyT)
| NONE => mk_var(v, dummyT))
| cvt (Metis.Term.Fn ("ti", [Metis.Term.Fn ("=",[]), _])) =
Const ("op =", HOLogic.typeT)
| cvt (Metis.Term.Fn ("ti", [Metis.Term.Fn (x,[]), ty])) =
(case SPR.strip_prefix SFC.const_prefix x of
SOME c => Const (SPR.invert_const c, dummyT)
| NONE => (*Not a constant. Is it a fixed variable??*)
case SPR.strip_prefix SFC.fixed_var_prefix x of
SOME v => Free (v, fol_type_to_isa ctxt ty)
| NONE => error ("fol_term_to_hol_FT bad constant: " ^ x))
| cvt (Metis.Term.Fn ("ti", [Metis.Term.Fn (".",[tm1,tm2]), _])) =
cvt tm1 $ cvt tm2
| cvt (Metis.Term.Fn (".",[tm1,tm2])) = (*untyped application*)
cvt tm1 $ cvt tm2
| cvt (Metis.Term.Fn ("{}", [arg])) = cvt arg (*hBOOL*)
| cvt (Metis.Term.Fn ("=", [tm1,tm2])) =
list_comb(Const ("op =", HOLogic.typeT), map cvt [tm1,tm2])
| cvt (t as Metis.Term.Fn (x, [])) =
(case SPR.strip_prefix SFC.const_prefix x of
SOME c => Const (SPR.invert_const c, dummyT)
| NONE => (*Not a constant. Is it a fixed variable??*)
case SPR.strip_prefix SFC.fixed_var_prefix x of
SOME v => Free (v, dummyT)
| NONE => (trace_msg (fn () => "fol_term_to_hol_FT bad const: " ^ x);
fol_term_to_hol_RAW ctxt t))
| cvt t = (trace_msg (fn () => "fol_term_to_hol_FT bad term: " ^ Metis.Term.toString t);
fol_term_to_hol_RAW ctxt t)
in cvt fol_tm end;
fun fol_term_to_hol ctxt FO = fol_term_to_hol_RAW ctxt
| fol_term_to_hol ctxt HO = fol_term_to_hol_RAW ctxt
| fol_term_to_hol ctxt FT = fol_term_to_hol_FT ctxt;
fun fol_terms_to_hol ctxt mode fol_tms =
let val ts = map (fol_term_to_hol ctxt mode) fol_tms
val _ = trace_msg (fn () => " calling type inference:")
val _ = app (fn t => trace_msg (fn () => Syntax.string_of_term ctxt t)) ts
val ts' = infer_types ctxt ts;
val _ = app (fn t => trace_msg
(fn () => " final term: " ^ Syntax.string_of_term ctxt t ^
" of type " ^ Syntax.string_of_typ ctxt (type_of t)))
ts'
in ts' end;
fun mk_not (Const ("Not", _) $ b) = b
| mk_not b = HOLogic.mk_not b;
val metis_eq = Metis.Term.Fn ("=", []);
(* ------------------------------------------------------------------------- *)
(* FOL step Inference Rules *)
(* ------------------------------------------------------------------------- *)
(*for debugging only*)
fun print_thpair (fth,th) =
(trace_msg (fn () => "=============================================");
trace_msg (fn () => "Metis: " ^ Metis.Thm.toString fth);
trace_msg (fn () => "Isabelle: " ^ Display.string_of_thm_without_context th));
fun lookth thpairs (fth : Metis.Thm.thm) =
the (AList.lookup (uncurry Metis.Thm.equal) thpairs fth)
handle Option => error ("Failed to find a Metis theorem " ^ Metis.Thm.toString fth);
fun is_TrueI th = Thm.eq_thm(TrueI,th);
fun cterm_incr_types thy idx = cterm_of thy o (map_types (Logic.incr_tvar idx));
fun inst_excluded_middle thy i_atm =
let val th = EXCLUDED_MIDDLE
val [vx] = Term.add_vars (prop_of th) []
val substs = [(cterm_of thy (Var vx), cterm_of thy i_atm)]
in cterm_instantiate substs th end;
(* INFERENCE RULE: AXIOM *)
fun axiom_inf thpairs th = incr_indexes 1 (lookth thpairs th);
(*This causes variables to have an index of 1 by default. SEE ALSO mk_var above.*)
(* INFERENCE RULE: ASSUME *)
fun assume_inf ctxt mode atm =
inst_excluded_middle
(ProofContext.theory_of ctxt)
(singleton (fol_terms_to_hol ctxt mode) (Metis.Term.Fn atm));
(* INFERENCE RULE: INSTANTIATE (Subst). Type instantiations are ignored. Trying to reconstruct
them admits new possibilities of errors, e.g. concerning sorts. Instead we try to arrange
that new TVars are distinct and that types can be inferred from terms.*)
fun inst_inf ctxt mode thpairs fsubst th =
let val thy = ProofContext.theory_of ctxt
val i_th = lookth thpairs th
val i_th_vars = Term.add_vars (prop_of i_th) []
fun find_var x = the (List.find (fn ((a,_),_) => a=x) i_th_vars)
fun subst_translation (x,y) =
let val v = find_var x
val t = fol_term_to_hol ctxt mode y (*we call infer_types below*)
in SOME (cterm_of thy (Var v), t) end
handle Option =>
(trace_msg (fn() => "List.find failed for the variable " ^ x ^
" in " ^ Display.string_of_thm ctxt i_th);
NONE)
fun remove_typeinst (a, t) =
case SPR.strip_prefix SFC.schematic_var_prefix a of
SOME b => SOME (b, t)
| NONE => case SPR.strip_prefix SFC.tvar_prefix a of
SOME _ => NONE (*type instantiations are forbidden!*)
| NONE => SOME (a,t) (*internal Metis var?*)
val _ = trace_msg (fn () => " isa th: " ^ Display.string_of_thm ctxt i_th)
val substs = map_filter remove_typeinst (Metis.Subst.toList fsubst)
val (vars,rawtms) = ListPair.unzip (map_filter subst_translation substs)
val tms = infer_types ctxt rawtms;
val ctm_of = cterm_incr_types thy (1 + Thm.maxidx_of i_th)
val substs' = ListPair.zip (vars, map ctm_of tms)
val _ = trace_msg (fn () =>
cat_lines ("subst_translations:" ::
(substs' |> map (fn (x, y) =>
Syntax.string_of_term ctxt (term_of x) ^ " |-> " ^
Syntax.string_of_term ctxt (term_of y)))));
in cterm_instantiate substs' i_th
handle THM (msg, _, _) => error ("metis error (inst_inf): " ^ msg)
end;
(* INFERENCE RULE: RESOLVE *)
(*Like RSN, but we rename apart only the type variables. Vars here typically have an index
of 1, and the use of RSN would increase this typically to 3. Instantiations of those Vars
could then fail. See comment on mk_var.*)
fun resolve_inc_tyvars(tha,i,thb) =
let val tha = Drule.incr_type_indexes (1 + Thm.maxidx_of thb) tha
val ths = Seq.list_of (Thm.bicompose false (false,tha,nprems_of tha) i thb)
in
case distinct Thm.eq_thm ths of
[th] => th
| _ => raise THM ("resolve_inc_tyvars: unique result expected", i, [tha,thb])
end;
fun resolve_inf ctxt mode thpairs atm th1 th2 =
let
val i_th1 = lookth thpairs th1 and i_th2 = lookth thpairs th2
val _ = trace_msg (fn () => " isa th1 (pos): " ^ Display.string_of_thm ctxt i_th1)
val _ = trace_msg (fn () => " isa th2 (neg): " ^ Display.string_of_thm ctxt i_th2)
in
if is_TrueI i_th1 then i_th2 (*Trivial cases where one operand is type info*)
else if is_TrueI i_th2 then i_th1
else
let
val i_atm = singleton (fol_terms_to_hol ctxt mode) (Metis.Term.Fn atm)
val _ = trace_msg (fn () => " atom: " ^ Syntax.string_of_term ctxt i_atm)
val prems_th1 = prems_of i_th1
val prems_th2 = prems_of i_th2
val index_th1 = get_index (mk_not i_atm) prems_th1
handle Empty => error "Failed to find literal in th1"
val _ = trace_msg (fn () => " index_th1: " ^ Int.toString index_th1)
val index_th2 = get_index i_atm prems_th2
handle Empty => error "Failed to find literal in th2"
val _ = trace_msg (fn () => " index_th2: " ^ Int.toString index_th2)
in resolve_inc_tyvars (Meson.select_literal index_th1 i_th1, index_th2, i_th2) end
end;
(* INFERENCE RULE: REFL *)
val refl_x = cterm_of @{theory} (Var (hd (Term.add_vars (prop_of REFL_THM) [])));
val refl_idx = 1 + Thm.maxidx_of REFL_THM;
fun refl_inf ctxt mode t =
let val thy = ProofContext.theory_of ctxt
val i_t = singleton (fol_terms_to_hol ctxt mode) t
val _ = trace_msg (fn () => " term: " ^ Syntax.string_of_term ctxt i_t)
val c_t = cterm_incr_types thy refl_idx i_t
in cterm_instantiate [(refl_x, c_t)] REFL_THM end;
fun get_ty_arg_size _ (Const ("op =", _)) = 0 (*equality has no type arguments*)
| get_ty_arg_size thy (Const (c, _)) = (SPR.num_typargs thy c handle TYPE _ => 0)
| get_ty_arg_size _ _ = 0;
(* INFERENCE RULE: EQUALITY *)
fun equality_inf ctxt mode (pos, atm) fp fr =
let val thy = ProofContext.theory_of ctxt
val m_tm = Metis.Term.Fn atm
val [i_atm,i_tm] = fol_terms_to_hol ctxt mode [m_tm, fr]
val _ = trace_msg (fn () => "sign of the literal: " ^ Bool.toString pos)
fun replace_item_list lx 0 (_::ls) = lx::ls
| replace_item_list lx i (l::ls) = l :: replace_item_list lx (i-1) ls
fun path_finder_FO tm [] = (tm, Term.Bound 0)
| path_finder_FO tm (p::ps) =
let val (tm1,args) = Term.strip_comb tm
val adjustment = get_ty_arg_size thy tm1
val p' = if adjustment > p then p else p-adjustment
val tm_p = List.nth(args,p')
handle Subscript => error ("equality_inf: " ^ Int.toString p ^ " adj " ^
Int.toString adjustment ^ " term " ^ Syntax.string_of_term ctxt tm)
val _ = trace_msg (fn () => "path_finder: " ^ Int.toString p ^
" " ^ Syntax.string_of_term ctxt tm_p)
val (r,t) = path_finder_FO tm_p ps
in
(r, list_comb (tm1, replace_item_list t p' args))
end
fun path_finder_HO tm [] = (tm, Term.Bound 0)
| path_finder_HO (t$u) (0::ps) = (fn(x,y) => (x, y$u)) (path_finder_HO t ps)
| path_finder_HO (t$u) (_::ps) = (fn(x,y) => (x, t$y)) (path_finder_HO u ps)
fun path_finder_FT tm [] _ = (tm, Term.Bound 0)
| path_finder_FT tm (0::ps) (Metis.Term.Fn ("ti", [t1, _])) =
path_finder_FT tm ps t1
| path_finder_FT (t$u) (0::ps) (Metis.Term.Fn (".", [t1, _])) =
(fn(x,y) => (x, y$u)) (path_finder_FT t ps t1)
| path_finder_FT (t$u) (1::ps) (Metis.Term.Fn (".", [_, t2])) =
(fn(x,y) => (x, t$y)) (path_finder_FT u ps t2)
| path_finder_FT tm ps t = error ("equality_inf, path_finder_FT: path = " ^
space_implode " " (map Int.toString ps) ^
" isa-term: " ^ Syntax.string_of_term ctxt tm ^
" fol-term: " ^ Metis.Term.toString t)
fun path_finder FO tm ps _ = path_finder_FO tm ps
| path_finder HO (tm as Const("op =",_) $ _ $ _) (p::ps) _ =
(*equality: not curried, as other predicates are*)
if p=0 then path_finder_HO tm (0::1::ps) (*select first operand*)
else path_finder_HO tm (p::ps) (*1 selects second operand*)
| path_finder HO tm (_ :: ps) (Metis.Term.Fn ("{}", [_])) =
path_finder_HO tm ps (*if not equality, ignore head to skip hBOOL*)
| path_finder FT (tm as Const("op =",_) $ _ $ _) (p::ps)
(Metis.Term.Fn ("=", [t1,t2])) =
(*equality: not curried, as other predicates are*)
if p=0 then path_finder_FT tm (0::1::ps)
(Metis.Term.Fn (".", [Metis.Term.Fn (".", [metis_eq,t1]), t2]))
(*select first operand*)
else path_finder_FT tm (p::ps)
(Metis.Term.Fn (".", [metis_eq,t2]))
(*1 selects second operand*)
| path_finder FT tm (_ :: ps) (Metis.Term.Fn ("{}", [t1])) = path_finder_FT tm ps t1
(*if not equality, ignore head to skip the hBOOL predicate*)
| path_finder FT tm ps t = path_finder_FT tm ps t (*really an error case!*)
fun path_finder_lit ((nt as Term.Const ("Not", _)) $ tm_a) idx =
let val (tm, tm_rslt) = path_finder mode tm_a idx m_tm
in (tm, nt $ tm_rslt) end
| path_finder_lit tm_a idx = path_finder mode tm_a idx m_tm
val (tm_subst, body) = path_finder_lit i_atm fp
val tm_abs = Term.Abs("x", Term.type_of tm_subst, body)
val _ = trace_msg (fn () => "abstraction: " ^ Syntax.string_of_term ctxt tm_abs)
val _ = trace_msg (fn () => "i_tm: " ^ Syntax.string_of_term ctxt i_tm)
val _ = trace_msg (fn () => "located term: " ^ Syntax.string_of_term ctxt tm_subst)
val imax = maxidx_of_term (i_tm $ tm_abs $ tm_subst) (*ill typed but gives right max*)
val subst' = incr_indexes (imax+1) (if pos then subst_em else ssubst_em)
val _ = trace_msg (fn () => "subst' " ^ Display.string_of_thm ctxt subst')
val eq_terms = map (pairself (cterm_of thy))
(ListPair.zip (OldTerm.term_vars (prop_of subst'), [tm_abs, tm_subst, i_tm]))
in cterm_instantiate eq_terms subst' end;
val factor = Seq.hd o distinct_subgoals_tac;
fun step _ _ thpairs (fol_th, Metis.Proof.Axiom _) = factor (axiom_inf thpairs fol_th)
| step ctxt mode _ (_, Metis.Proof.Assume f_atm) = assume_inf ctxt mode f_atm
| step ctxt mode thpairs (_, Metis.Proof.Subst (f_subst, f_th1)) =
factor (inst_inf ctxt mode thpairs f_subst f_th1)
| step ctxt mode thpairs (_, Metis.Proof.Resolve(f_atm, f_th1, f_th2)) =
factor (resolve_inf ctxt mode thpairs f_atm f_th1 f_th2)
| step ctxt mode _ (_, Metis.Proof.Refl f_tm) = refl_inf ctxt mode f_tm
| step ctxt mode _ (_, Metis.Proof.Equality (f_lit, f_p, f_r)) =
equality_inf ctxt mode f_lit f_p f_r;
fun real_literal (_, (c, _)) = not (String.isPrefix SFC.class_prefix c);
fun translate _ _ thpairs [] = thpairs
| translate mode ctxt thpairs ((fol_th, inf) :: infpairs) =
let val _ = trace_msg (fn () => "=============================================")
val _ = trace_msg (fn () => "METIS THM: " ^ Metis.Thm.toString fol_th)
val _ = trace_msg (fn () => "INFERENCE: " ^ Metis.Proof.inferenceToString inf)
val th = Meson.flexflex_first_order (step ctxt mode thpairs (fol_th, inf))
val _ = trace_msg (fn () => "ISABELLE THM: " ^ Display.string_of_thm ctxt th)
val _ = trace_msg (fn () => "=============================================")
val n_metis_lits =
length (filter real_literal (Metis.LiteralSet.toList (Metis.Thm.clause fol_th)))
in
if nprems_of th = n_metis_lits then ()
else error "Metis: proof reconstruction has gone wrong";
translate mode ctxt ((fol_th, th) :: thpairs) infpairs
end;
(*Determining which axiom clauses are actually used*)
fun used_axioms axioms (th, Metis.Proof.Axiom _) = SOME (lookth axioms th)
| used_axioms _ _ = NONE;
(* ------------------------------------------------------------------------- *)
(* Translation of HO Clauses *)
(* ------------------------------------------------------------------------- *)
fun cnf_th thy th = hd (Sledgehammer_Fact_Preprocessor.cnf_axiom thy th);
val equal_imp_fequal' = cnf_th @{theory} @{thm equal_imp_fequal};
val fequal_imp_equal' = cnf_th @{theory} @{thm fequal_imp_equal};
val comb_I = cnf_th @{theory} SHC.comb_I;
val comb_K = cnf_th @{theory} SHC.comb_K;
val comb_B = cnf_th @{theory} SHC.comb_B;
val comb_C = cnf_th @{theory} SHC.comb_C;
val comb_S = cnf_th @{theory} SHC.comb_S;
fun type_ext thy tms =
let val subs = Sledgehammer_Fact_Filter.tfree_classes_of_terms tms
val supers = Sledgehammer_Fact_Filter.tvar_classes_of_terms tms
and tycons = Sledgehammer_Fact_Filter.type_consts_of_terms thy tms
val (supers', arity_clauses) = SFC.make_arity_clauses thy tycons supers
val classrel_clauses = SFC.make_classrel_clauses thy subs supers'
in map classrel_cls classrel_clauses @ map arity_cls arity_clauses
end;
(* ------------------------------------------------------------------------- *)
(* Logic maps manage the interface between HOL and first-order logic. *)
(* ------------------------------------------------------------------------- *)
type logic_map =
{axioms : (Metis.Thm.thm * thm) list,
tfrees : SFC.type_literal list};
fun const_in_metis c (pred, tm_list) =
let
fun in_mterm (Metis.Term.Var _) = false
| in_mterm (Metis.Term.Fn (".", tm_list)) = exists in_mterm tm_list
| in_mterm (Metis.Term.Fn (nm, tm_list)) = c=nm orelse exists in_mterm tm_list
in c = pred orelse exists in_mterm tm_list end;
(*Extract TFree constraints from context to include as conjecture clauses*)
fun init_tfrees ctxt =
let fun add ((a,i),s) Ts = if i = ~1 then TFree(a,s) :: Ts else Ts
in SFC.add_typs (Vartab.fold add (#2 (Variable.constraints_of ctxt)) []) end;
(*transform isabelle type / arity clause to metis clause *)
fun add_type_thm [] lmap = lmap
| add_type_thm ((ith, mth) :: cls) {axioms, tfrees} =
add_type_thm cls {axioms = (mth, ith) :: axioms,
tfrees = tfrees}
(*Insert non-logical axioms corresponding to all accumulated TFrees*)
fun add_tfrees {axioms, tfrees} : logic_map =
{axioms = (map (fn tf => (metis_of_tfree tf, TrueI)) (distinct op= tfrees)) @ axioms,
tfrees = tfrees};
fun string_of_mode FO = "FO"
| string_of_mode HO = "HO"
| string_of_mode FT = "FT"
(* Function to generate metis clauses, including comb and type clauses *)
fun build_map mode0 ctxt cls ths =
let val thy = ProofContext.theory_of ctxt
(*The modes FO and FT are sticky. HO can be downgraded to FO.*)
fun set_mode FO = FO
| set_mode HO = if forall (Meson.is_fol_term thy o prop_of) (cls@ths) then FO else HO
| set_mode FT = FT
val mode = set_mode mode0
(*transform isabelle clause to metis clause *)
fun add_thm is_conjecture ith {axioms, tfrees} : logic_map =
let val (mth, tfree_lits) = hol_thm_to_fol is_conjecture ctxt mode ith
in
{axioms = (mth, Meson.make_meta_clause ith) :: axioms,
tfrees = union (op =) tfree_lits tfrees}
end;
val lmap0 = fold (add_thm true) cls {axioms = [], tfrees = init_tfrees ctxt}
val lmap = fold (add_thm false) ths (add_tfrees lmap0)
val clause_lists = map (Metis.Thm.clause o #1) (#axioms lmap)
fun used c = exists (Metis.LiteralSet.exists (const_in_metis c o #2)) clause_lists
(*Now check for the existence of certain combinators*)
val thI = if used "c_COMBI" then [comb_I] else []
val thK = if used "c_COMBK" then [comb_K] else []
val thB = if used "c_COMBB" then [comb_B] else []
val thC = if used "c_COMBC" then [comb_C] else []
val thS = if used "c_COMBS" then [comb_S] else []
val thEQ = if used "c_fequal" then [fequal_imp_equal', equal_imp_fequal'] else []
val lmap' = if mode=FO then lmap
else fold (add_thm false) (thEQ @ thS @ thC @ thB @ thK @ thI) lmap
in
(mode, add_type_thm (type_ext thy (map prop_of (cls @ ths))) lmap')
end;
fun refute cls =
Metis.Resolution.loop (Metis.Resolution.new Metis.Resolution.default cls);
fun is_false t = t aconv (HOLogic.mk_Trueprop HOLogic.false_const);
fun common_thm ths1 ths2 = exists (member Thm.eq_thm ths1) (map Meson.make_meta_clause ths2);
exception METIS of string;
(* Main function to start metis prove and reconstruction *)
fun FOL_SOLVE mode ctxt cls ths0 =
let val thy = ProofContext.theory_of ctxt
val th_cls_pairs =
map (fn th => (Thm.get_name_hint th, Sledgehammer_Fact_Preprocessor.cnf_axiom thy th)) ths0
val ths = maps #2 th_cls_pairs
val _ = trace_msg (fn () => "FOL_SOLVE: CONJECTURE CLAUSES")
val _ = app (fn th => trace_msg (fn () => Display.string_of_thm ctxt th)) cls
val _ = trace_msg (fn () => "THEOREM CLAUSES")
val _ = app (fn th => trace_msg (fn () => Display.string_of_thm ctxt th)) ths
val (mode, {axioms,tfrees}) = build_map mode ctxt cls ths
val _ = if null tfrees then ()
else (trace_msg (fn () => "TFREE CLAUSES");
app (fn tf => trace_msg (fn _ => SFC.tptp_of_typeLit true tf)) tfrees)
val _ = trace_msg (fn () => "CLAUSES GIVEN TO METIS")
val thms = map #1 axioms
val _ = app (fn th => trace_msg (fn () => Metis.Thm.toString th)) thms
val _ = trace_msg (fn () => "mode = " ^ string_of_mode mode)
val _ = trace_msg (fn () => "START METIS PROVE PROCESS")
in
case filter (is_false o prop_of) cls of
false_th::_ => [false_th RS @{thm FalseE}]
| [] =>
case refute thms of
Metis.Resolution.Contradiction mth =>
let val _ = trace_msg (fn () => "METIS RECONSTRUCTION START: " ^
Metis.Thm.toString mth)
val ctxt' = fold Variable.declare_constraints (map prop_of cls) ctxt
(*add constraints arising from converting goal to clause form*)
val proof = Metis.Proof.proof mth
val result = translate mode ctxt' axioms proof
and used = map_filter (used_axioms axioms) proof
val _ = trace_msg (fn () => "METIS COMPLETED...clauses actually used:")
val _ = app (fn th => trace_msg (fn () => Display.string_of_thm ctxt th)) used
val unused = th_cls_pairs |> map_filter (fn (name, cls) =>
if common_thm used cls then NONE else SOME name)
in
if null unused then ()
else warning ("Metis: unused theorems " ^ commas_quote unused);
case result of
(_,ith)::_ =>
(trace_msg (fn () => "success: " ^ Display.string_of_thm ctxt ith);
[ith])
| _ => (trace_msg (fn () => "Metis: no result");
[])
end
| Metis.Resolution.Satisfiable _ =>
(trace_msg (fn () => "Metis: No first-order proof with the lemmas supplied");
[])
end;
fun metis_general_tac mode ctxt ths i st0 =
let val _ = trace_msg (fn () =>
"Metis called with theorems " ^ cat_lines (map (Display.string_of_thm ctxt) ths))
in
if exists_type Sledgehammer_Fact_Preprocessor.type_has_topsort (prop_of st0)
then raise METIS "Metis: Proof state contains the universal sort {}"
else
(Meson.MESON Sledgehammer_Fact_Preprocessor.neg_clausify
(fn cls => resolve_tac (FOL_SOLVE mode ctxt cls ths) 1) ctxt i
THEN Sledgehammer_Fact_Preprocessor.expand_defs_tac st0) st0
end
handle METIS s => (warning ("Metis: " ^ s); Seq.empty);
val metis_tac = metis_general_tac HO;
val metisF_tac = metis_general_tac FO;
val metisFT_tac = metis_general_tac FT;
fun method name mode comment = Method.setup name (Attrib.thms >> (fn ths => fn ctxt =>
SIMPLE_METHOD' (CHANGED_PROP o metis_general_tac mode ctxt ths))) comment;
val setup =
type_lits_setup #>
method @{binding metis} HO "METIS for FOL & HOL problems" #>
method @{binding metisF} FO "METIS for FOL problems" #>
method @{binding metisFT} FT "METIS with fully-typed translation" #>
Method.setup @{binding finish_clausify}
(Scan.succeed (K (SIMPLE_METHOD (Sledgehammer_Fact_Preprocessor.expand_defs_tac refl))))
"cleanup after conversion to clauses";
end;