(* Title: HOL/Tools/cnf_funcs.ML
ID: $Id$
Author: Alwen Tiu, QSL Team, LORIA (http://qsl.loria.fr)
Author: Tjark Weber
Copyright 2005-2006
Description:
This file contains functions and tactics to transform a formula into
Conjunctive Normal Form (CNF).
A formula in CNF is of the following form:
(x11 | x12 | ... | x1n) & ... & (xm1 | xm2 | ... | xmk)
False
True
where each xij is a literal (a positive or negative atomic Boolean term),
i.e. the formula is a conjunction of disjunctions of literals, or
"False", or "True".
A (non-empty) disjunction of literals is referred to as "clause".
For the purpose of SAT proof reconstruction, we also make use of another
representation of clauses, which we call the "raw clauses".
Raw clauses are of the form
[..., x1', x2', ..., xn'] |- False ,
where each xi is a literal, and each xi' is the negation normal form of ~xi.
Literals are successively removed from the hyps of raw clauses by resolution
during SAT proof reconstruction.
*)
signature CNF =
sig
val is_atom : Term.term -> bool
val is_literal : Term.term -> bool
val is_clause : Term.term -> bool
val clause_is_trivial : Term.term -> bool
val clause2raw_thm : Thm.thm -> Thm.thm
val weakening_tac : int -> Tactical.tactic (* removes the first hypothesis of a subgoal *)
val make_cnf_thm : theory -> Term.term -> Thm.thm
val make_cnfx_thm : theory -> Term.term -> Thm.thm
val cnf_rewrite_tac : int -> Tactical.tactic (* converts all prems of a subgoal to CNF *)
val cnfx_rewrite_tac : int -> Tactical.tactic (* converts all prems of a subgoal to (almost) definitional CNF *)
end;
structure cnf : CNF =
struct
fun thm_by_auto (G : string) : thm =
prove_goal (the_context ()) G (fn prems => [cut_facts_tac prems 1, Auto_tac]);
(* Thm.thm *)
val clause2raw_notE = thm_by_auto "[| P; ~P |] ==> False";
val clause2raw_not_disj = thm_by_auto "[| ~P; ~Q |] ==> ~(P | Q)";
val clause2raw_not_not = thm_by_auto "P ==> ~~P";
val iff_refl = thm_by_auto "(P::bool) = P";
val iff_trans = thm_by_auto "[| (P::bool) = Q; Q = R |] ==> P = R";
val conj_cong = thm_by_auto "[| P = P'; Q = Q' |] ==> (P & Q) = (P' & Q')";
val disj_cong = thm_by_auto "[| P = P'; Q = Q' |] ==> (P | Q) = (P' | Q')";
val make_nnf_imp = thm_by_auto "[| (~P) = P'; Q = Q' |] ==> (P --> Q) = (P' | Q')";
val make_nnf_iff = thm_by_auto "[| P = P'; (~P) = NP; Q = Q'; (~Q) = NQ |] ==> (P = Q) = ((P' | NQ) & (NP | Q'))";
val make_nnf_not_false = thm_by_auto "(~False) = True";
val make_nnf_not_true = thm_by_auto "(~True) = False";
val make_nnf_not_conj = thm_by_auto "[| (~P) = P'; (~Q) = Q' |] ==> (~(P & Q)) = (P' | Q')";
val make_nnf_not_disj = thm_by_auto "[| (~P) = P'; (~Q) = Q' |] ==> (~(P | Q)) = (P' & Q')";
val make_nnf_not_imp = thm_by_auto "[| P = P'; (~Q) = Q' |] ==> (~(P --> Q)) = (P' & Q')";
val make_nnf_not_iff = thm_by_auto "[| P = P'; (~P) = NP; Q = Q'; (~Q) = NQ |] ==> (~(P = Q)) = ((P' | Q') & (NP | NQ))";
val make_nnf_not_not = thm_by_auto "P = P' ==> (~~P) = P'";
val simp_TF_conj_True_l = thm_by_auto "[| P = True; Q = Q' |] ==> (P & Q) = Q'";
val simp_TF_conj_True_r = thm_by_auto "[| P = P'; Q = True |] ==> (P & Q) = P'";
val simp_TF_conj_False_l = thm_by_auto "P = False ==> (P & Q) = False";
val simp_TF_conj_False_r = thm_by_auto "Q = False ==> (P & Q) = False";
val simp_TF_disj_True_l = thm_by_auto "P = True ==> (P | Q) = True";
val simp_TF_disj_True_r = thm_by_auto "Q = True ==> (P | Q) = True";
val simp_TF_disj_False_l = thm_by_auto "[| P = False; Q = Q' |] ==> (P | Q) = Q'";
val simp_TF_disj_False_r = thm_by_auto "[| P = P'; Q = False |] ==> (P | Q) = P'";
val make_cnf_disj_conj_l = thm_by_auto "[| (P | R) = PR; (Q | R) = QR |] ==> ((P & Q) | R) = (PR & QR)";
val make_cnf_disj_conj_r = thm_by_auto "[| (P | Q) = PQ; (P | R) = PR |] ==> (P | (Q & R)) = (PQ & PR)";
val make_cnfx_disj_ex_l = thm_by_auto "((EX (x::bool). P x) | Q) = (EX x. P x | Q)";
val make_cnfx_disj_ex_r = thm_by_auto "(P | (EX (x::bool). Q x)) = (EX x. P | Q x)";
val make_cnfx_newlit = thm_by_auto "(P | Q) = (EX x. (P | x) & (Q | ~x))";
val make_cnfx_ex_cong = thm_by_auto "(ALL (x::bool). P x = Q x) ==> (EX x. P x) = (EX x. Q x)";
val weakening_thm = thm_by_auto "[| P; Q |] ==> Q";
val cnftac_eq_imp = thm_by_auto "[| P = Q; P |] ==> Q";
(* Term.term -> bool *)
fun is_atom (Const ("False", _)) = false
| is_atom (Const ("True", _)) = false
| is_atom (Const ("op &", _) $ _ $ _) = false
| is_atom (Const ("op |", _) $ _ $ _) = false
| is_atom (Const ("op -->", _) $ _ $ _) = false
| is_atom (Const ("op =", Type ("fun", Type ("bool", []) :: _)) $ _ $ _) = false
| is_atom (Const ("Not", _) $ _) = false
| is_atom _ = true;
(* Term.term -> bool *)
fun is_literal (Const ("Not", _) $ x) = is_atom x
| is_literal x = is_atom x;
(* Term.term -> bool *)
fun is_clause (Const ("op |", _) $ x $ y) = is_clause x andalso is_clause y
| is_clause x = is_literal x;
(* ------------------------------------------------------------------------- *)
(* clause_is_trivial: a clause is trivially true if it contains both an atom *)
(* and the atom's negation *)
(* ------------------------------------------------------------------------- *)
(* Term.term -> bool *)
fun clause_is_trivial c =
let
(* Term.term -> Term.term list -> Term.term list *)
fun collect_literals (Const ("op |", _) $ x $ y) ls = collect_literals x (collect_literals y ls)
| collect_literals x ls = x :: ls
(* Term.term -> Term.term *)
fun dual (Const ("Not", _) $ x) = x
| dual x = HOLogic.Not $ x
(* Term.term list -> bool *)
fun has_duals [] = false
| has_duals (x::xs) = (dual x) mem xs orelse has_duals xs
in
has_duals (collect_literals c [])
end;
(* ------------------------------------------------------------------------- *)
(* clause2raw_thm: translates a clause into a raw clause, i.e. *)
(* [...] |- x1 | ... | xn *)
(* (where each xi is a literal) is translated to *)
(* [..., x1', ..., xn'] |- False , *)
(* where each xi' is the negation normal form of ~xi *)
(* ------------------------------------------------------------------------- *)
(* Thm.thm -> Thm.thm *)
fun clause2raw_thm clause =
let
(* eliminates negated disjunctions from the i-th premise, possibly *)
(* adding new premises, then continues with the (i+1)-th premise *)
(* int -> Thm.thm -> Thm.thm *)
fun not_disj_to_prem i thm =
if i > nprems_of thm then
thm
else
not_disj_to_prem (i+1) (Seq.hd (REPEAT_DETERM (rtac clause2raw_not_disj i) thm))
(* moves all premises to hyps, i.e. "[...] |- A1 ==> ... ==> An ==> B" *)
(* becomes "[..., A1, ..., An] |- B" *)
(* Thm.thm -> Thm.thm *)
fun prems_to_hyps thm =
fold (fn cprem => fn thm' =>
Thm.implies_elim thm' (Thm.assume cprem)) (cprems_of thm) thm
in
(* [...] |- ~(x1 | ... | xn) ==> False *)
(clause2raw_notE OF [clause])
(* [...] |- ~x1 ==> ... ==> ~xn ==> False *)
|> not_disj_to_prem 1
(* [...] |- x1' ==> ... ==> xn' ==> False *)
|> Seq.hd o TRYALL (rtac clause2raw_not_not)
(* [..., x1', ..., xn'] |- False *)
|> prems_to_hyps
end;
(* ------------------------------------------------------------------------- *)
(* inst_thm: instantiates a theorem with a list of terms *)
(* ------------------------------------------------------------------------- *)
fun inst_thm thy ts thm =
instantiate' [] (map (SOME o cterm_of thy) ts) thm;
(* ------------------------------------------------------------------------- *)
(* Naive CNF transformation *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* make_nnf_thm: produces a theorem of the form t = t', where t' is the *)
(* negation normal form (i.e. negation only occurs in front of atoms) *)
(* of t; implications ("-->") and equivalences ("=" on bool) are *)
(* eliminated (possibly causing an exponential blowup) *)
(* ------------------------------------------------------------------------- *)
(* Theory.theory -> Term.term -> Thm.thm *)
fun make_nnf_thm thy (Const ("op &", _) $ x $ y) =
let
val thm1 = make_nnf_thm thy x
val thm2 = make_nnf_thm thy y
in
conj_cong OF [thm1, thm2]
end
| make_nnf_thm thy (Const ("op |", _) $ x $ y) =
let
val thm1 = make_nnf_thm thy x
val thm2 = make_nnf_thm thy y
in
disj_cong OF [thm1, thm2]
end
| make_nnf_thm thy (Const ("op -->", _) $ x $ y) =
let
val thm1 = make_nnf_thm thy (HOLogic.Not $ x)
val thm2 = make_nnf_thm thy y
in
make_nnf_imp OF [thm1, thm2]
end
| make_nnf_thm thy (Const ("op =", Type ("fun", Type ("bool", []) :: _)) $ x $ y) =
let
val thm1 = make_nnf_thm thy x
val thm2 = make_nnf_thm thy (HOLogic.Not $ x)
val thm3 = make_nnf_thm thy y
val thm4 = make_nnf_thm thy (HOLogic.Not $ y)
in
make_nnf_iff OF [thm1, thm2, thm3, thm4]
end
| make_nnf_thm thy (Const ("Not", _) $ Const ("False", _)) =
make_nnf_not_false
| make_nnf_thm thy (Const ("Not", _) $ Const ("True", _)) =
make_nnf_not_true
| make_nnf_thm thy (Const ("Not", _) $ (Const ("op &", _) $ x $ y)) =
let
val thm1 = make_nnf_thm thy (HOLogic.Not $ x)
val thm2 = make_nnf_thm thy (HOLogic.Not $ y)
in
make_nnf_not_conj OF [thm1, thm2]
end
| make_nnf_thm thy (Const ("Not", _) $ (Const ("op |", _) $ x $ y)) =
let
val thm1 = make_nnf_thm thy (HOLogic.Not $ x)
val thm2 = make_nnf_thm thy (HOLogic.Not $ y)
in
make_nnf_not_disj OF [thm1, thm2]
end
| make_nnf_thm thy (Const ("Not", _) $ (Const ("op -->", _) $ x $ y)) =
let
val thm1 = make_nnf_thm thy x
val thm2 = make_nnf_thm thy (HOLogic.Not $ y)
in
make_nnf_not_imp OF [thm1, thm2]
end
| make_nnf_thm thy (Const ("Not", _) $ (Const ("op =", Type ("fun", Type ("bool", []) :: _)) $ x $ y)) =
let
val thm1 = make_nnf_thm thy x
val thm2 = make_nnf_thm thy (HOLogic.Not $ x)
val thm3 = make_nnf_thm thy y
val thm4 = make_nnf_thm thy (HOLogic.Not $ y)
in
make_nnf_not_iff OF [thm1, thm2, thm3, thm4]
end
| make_nnf_thm thy (Const ("Not", _) $ (Const ("Not", _) $ x)) =
let
val thm1 = make_nnf_thm thy x
in
make_nnf_not_not OF [thm1]
end
| make_nnf_thm thy t =
inst_thm thy [t] iff_refl;
(* ------------------------------------------------------------------------- *)
(* simp_True_False_thm: produces a theorem t = t', where t' is equivalent to *)
(* t, but simplified wrt. the following theorems: *)
(* (True & x) = x *)
(* (x & True) = x *)
(* (False & x) = False *)
(* (x & False) = False *)
(* (True | x) = True *)
(* (x | True) = True *)
(* (False | x) = x *)
(* (x | False) = x *)
(* No simplification is performed below connectives other than & and |. *)
(* Optimization: The right-hand side of a conjunction (disjunction) is *)
(* simplified only if the left-hand side does not simplify to False *)
(* (True, respectively). *)
(* ------------------------------------------------------------------------- *)
(* Theory.theory -> Term.term -> Thm.thm *)
fun simp_True_False_thm thy (Const ("op &", _) $ x $ y) =
let
val thm1 = simp_True_False_thm thy x
val x' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm1
in
if x' = HOLogic.false_const then
simp_TF_conj_False_l OF [thm1] (* (x & y) = False *)
else
let
val thm2 = simp_True_False_thm thy y
val y' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm2
in
if x' = HOLogic.true_const then
simp_TF_conj_True_l OF [thm1, thm2] (* (x & y) = y' *)
else if y' = HOLogic.false_const then
simp_TF_conj_False_r OF [thm2] (* (x & y) = False *)
else if y' = HOLogic.true_const then
simp_TF_conj_True_r OF [thm1, thm2] (* (x & y) = x' *)
else
conj_cong OF [thm1, thm2] (* (x & y) = (x' & y') *)
end
end
| simp_True_False_thm thy (Const ("op |", _) $ x $ y) =
let
val thm1 = simp_True_False_thm thy x
val x' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm1
in
if x' = HOLogic.true_const then
simp_TF_disj_True_l OF [thm1] (* (x | y) = True *)
else
let
val thm2 = simp_True_False_thm thy y
val y' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm2
in
if x' = HOLogic.false_const then
simp_TF_disj_False_l OF [thm1, thm2] (* (x | y) = y' *)
else if y' = HOLogic.true_const then
simp_TF_disj_True_r OF [thm2] (* (x | y) = True *)
else if y' = HOLogic.false_const then
simp_TF_disj_False_r OF [thm1, thm2] (* (x | y) = x' *)
else
disj_cong OF [thm1, thm2] (* (x | y) = (x' | y') *)
end
end
| simp_True_False_thm thy t =
inst_thm thy [t] iff_refl; (* t = t *)
(* ------------------------------------------------------------------------- *)
(* make_cnf_thm: given any HOL term 't', produces a theorem t = t', where t' *)
(* is in conjunction normal form. May cause an exponential blowup *)
(* in the length of the term. *)
(* ------------------------------------------------------------------------- *)
(* Theory.theory -> Term.term -> Thm.thm *)
fun make_cnf_thm thy t =
let
(* Term.term -> Thm.thm *)
fun make_cnf_thm_from_nnf (Const ("op &", _) $ x $ y) =
let
val thm1 = make_cnf_thm_from_nnf x
val thm2 = make_cnf_thm_from_nnf y
in
conj_cong OF [thm1, thm2]
end
| make_cnf_thm_from_nnf (Const ("op |", _) $ x $ y) =
let
(* produces a theorem "(x' | y') = t'", where x', y', and t' are in CNF *)
fun make_cnf_disj_thm (Const ("op &", _) $ x1 $ x2) y' =
let
val thm1 = make_cnf_disj_thm x1 y'
val thm2 = make_cnf_disj_thm x2 y'
in
make_cnf_disj_conj_l OF [thm1, thm2] (* ((x1 & x2) | y') = ((x1 | y')' & (x2 | y')') *)
end
| make_cnf_disj_thm x' (Const ("op &", _) $ y1 $ y2) =
let
val thm1 = make_cnf_disj_thm x' y1
val thm2 = make_cnf_disj_thm x' y2
in
make_cnf_disj_conj_r OF [thm1, thm2] (* (x' | (y1 & y2)) = ((x' | y1)' & (x' | y2)') *)
end
| make_cnf_disj_thm x' y' =
inst_thm thy [HOLogic.mk_disj (x', y')] iff_refl (* (x' | y') = (x' | y') *)
val thm1 = make_cnf_thm_from_nnf x
val thm2 = make_cnf_thm_from_nnf y
val x' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm1
val y' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm2
val disj_thm = disj_cong OF [thm1, thm2] (* (x | y) = (x' | y') *)
in
iff_trans OF [disj_thm, make_cnf_disj_thm x' y']
end
| make_cnf_thm_from_nnf t =
inst_thm thy [t] iff_refl
(* convert 't' to NNF first *)
val nnf_thm = make_nnf_thm thy t
val nnf = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) nnf_thm
(* then simplify wrt. True/False (this should preserve NNF) *)
val simp_thm = simp_True_False_thm thy nnf
val simp = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) simp_thm
(* finally, convert to CNF (this should preserve the simplification) *)
val cnf_thm = make_cnf_thm_from_nnf simp
in
iff_trans OF [iff_trans OF [nnf_thm, simp_thm], cnf_thm]
end;
(* ------------------------------------------------------------------------- *)
(* CNF transformation by introducing new literals *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* make_cnfx_thm: given any HOL term 't', produces a theorem t = t', where *)
(* t' is almost in conjunction normal form, except that conjunctions *)
(* and existential quantifiers may be nested. (Use e.g. 'REPEAT_DETERM *)
(* (etac exE i ORELSE etac conjE i)' afterwards to normalize.) May *)
(* introduce new (existentially bound) literals. Note: the current *)
(* implementation calls 'make_nnf_thm', causing an exponential blowup *)
(* in the case of nested equivalences. *)
(* ------------------------------------------------------------------------- *)
(* Theory.theory -> Term.term -> Thm.thm *)
fun make_cnfx_thm thy t =
let
val var_id = ref 0 (* properly initialized below *)
(* unit -> Term.term *)
fun new_free () =
Free ("cnfx_" ^ string_of_int (inc var_id), HOLogic.boolT)
(* Term.term -> Thm.thm *)
fun make_cnfx_thm_from_nnf (Const ("op &", _) $ x $ y) =
let
val thm1 = make_cnfx_thm_from_nnf x
val thm2 = make_cnfx_thm_from_nnf y
in
conj_cong OF [thm1, thm2]
end
| make_cnfx_thm_from_nnf (Const ("op |", _) $ x $ y) =
if is_clause x andalso is_clause y then
inst_thm thy [HOLogic.mk_disj (x, y)] iff_refl
else if is_literal y orelse is_literal x then let
(* produces a theorem "(x' | y') = t'", where x', y', and t' are *)
(* almost in CNF, and x' or y' is a literal *)
fun make_cnfx_disj_thm (Const ("op &", _) $ x1 $ x2) y' =
let
val thm1 = make_cnfx_disj_thm x1 y'
val thm2 = make_cnfx_disj_thm x2 y'
in
make_cnf_disj_conj_l OF [thm1, thm2] (* ((x1 & x2) | y') = ((x1 | y')' & (x2 | y')') *)
end
| make_cnfx_disj_thm x' (Const ("op &", _) $ y1 $ y2) =
let
val thm1 = make_cnfx_disj_thm x' y1
val thm2 = make_cnfx_disj_thm x' y2
in
make_cnf_disj_conj_r OF [thm1, thm2] (* (x' | (y1 & y2)) = ((x' | y1)' & (x' | y2)') *)
end
| make_cnfx_disj_thm (Const ("Ex", _) $ x') y' =
let
val thm1 = inst_thm thy [x', y'] make_cnfx_disj_ex_l (* ((Ex x') | y') = (Ex (x' | y')) *)
val var = new_free ()
val thm2 = make_cnfx_disj_thm (betapply (x', var)) y' (* (x' | y') = body' *)
val thm3 = forall_intr (cterm_of thy var) thm2 (* !!v. (x' | y') = body' *)
val thm4 = strip_shyps (thm3 COMP allI) (* ALL v. (x' | y') = body' *)
val thm5 = strip_shyps (thm4 RS make_cnfx_ex_cong) (* (EX v. (x' | y')) = (EX v. body') *)
in
iff_trans OF [thm1, thm5] (* ((Ex x') | y') = (Ex v. body') *)
end
| make_cnfx_disj_thm x' (Const ("Ex", _) $ y') =
let
val thm1 = inst_thm thy [x', y'] make_cnfx_disj_ex_r (* (x' | (Ex y')) = (Ex (x' | y')) *)
val var = new_free ()
val thm2 = make_cnfx_disj_thm x' (betapply (y', var)) (* (x' | y') = body' *)
val thm3 = forall_intr (cterm_of thy var) thm2 (* !!v. (x' | y') = body' *)
val thm4 = strip_shyps (thm3 COMP allI) (* ALL v. (x' | y') = body' *)
val thm5 = strip_shyps (thm4 RS make_cnfx_ex_cong) (* (EX v. (x' | y')) = (EX v. body') *)
in
iff_trans OF [thm1, thm5] (* (x' | (Ex y')) = (EX v. body') *)
end
| make_cnfx_disj_thm x' y' =
inst_thm thy [HOLogic.mk_disj (x', y')] iff_refl (* (x' | y') = (x' | y') *)
val thm1 = make_cnfx_thm_from_nnf x
val thm2 = make_cnfx_thm_from_nnf y
val x' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm1
val y' = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) thm2
val disj_thm = disj_cong OF [thm1, thm2] (* (x | y) = (x' | y') *)
in
iff_trans OF [disj_thm, make_cnfx_disj_thm x' y']
end else let (* neither 'x' nor 'y' is a literal: introduce a fresh variable *)
val thm1 = inst_thm thy [x, y] make_cnfx_newlit (* (x | y) = EX v. (x | v) & (y | ~v) *)
val var = new_free ()
val body = HOLogic.mk_conj (HOLogic.mk_disj (x, var), HOLogic.mk_disj (y, HOLogic.Not $ var))
val thm2 = make_cnfx_thm_from_nnf body (* (x | v) & (y | ~v) = body' *)
val thm3 = forall_intr (cterm_of thy var) thm2 (* !!v. (x | v) & (y | ~v) = body' *)
val thm4 = strip_shyps (thm3 COMP allI) (* ALL v. (x | v) & (y | ~v) = body' *)
val thm5 = strip_shyps (thm4 RS make_cnfx_ex_cong) (* (EX v. (x | v) & (y | ~v)) = (EX v. body') *)
in
iff_trans OF [thm1, thm5]
end
| make_cnfx_thm_from_nnf t =
inst_thm thy [t] iff_refl
(* convert 't' to NNF first *)
val nnf_thm = make_nnf_thm thy t
val nnf = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) nnf_thm
(* then simplify wrt. True/False (this should preserve NNF) *)
val simp_thm = simp_True_False_thm thy nnf
val simp = (snd o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of) simp_thm
(* initialize var_id, in case the term already contains variables of the form "cnfx_<int>" *)
val _ = (var_id := fold (fn free => fn max =>
let
val (name, _) = dest_Free free
val idx = if String.isPrefix "cnfx_" name then
(Int.fromString o String.extract) (name, String.size "cnfx_", NONE)
else
NONE
in
Int.max (max, getOpt (idx, 0))
end) (term_frees simp) 0)
(* finally, convert to definitional CNF (this should preserve the simplification) *)
val cnfx_thm = make_cnfx_thm_from_nnf simp
in
iff_trans OF [iff_trans OF [nnf_thm, simp_thm], cnfx_thm]
end;
(* ------------------------------------------------------------------------- *)
(* Tactics *)
(* ------------------------------------------------------------------------- *)
(* ------------------------------------------------------------------------- *)
(* weakening_tac: removes the first hypothesis of the 'i'-th subgoal *)
(* ------------------------------------------------------------------------- *)
(* int -> Tactical.tactic *)
fun weakening_tac i =
dtac weakening_thm i THEN atac (i+1);
(* ------------------------------------------------------------------------- *)
(* cnf_rewrite_tac: converts all premises of the 'i'-th subgoal to CNF *)
(* (possibly causing an exponential blowup in the length of each *)
(* premise) *)
(* ------------------------------------------------------------------------- *)
(* int -> Tactical.tactic *)
fun cnf_rewrite_tac i =
(* cut the CNF formulas as new premises *)
METAHYPS (fn prems =>
let
val cnf_thms = map (fn pr => make_cnf_thm (theory_of_thm pr) ((HOLogic.dest_Trueprop o prop_of) pr)) prems
val cut_thms = map (fn (th, pr) => cnftac_eq_imp OF [th, pr]) (cnf_thms ~~ prems)
in
cut_facts_tac cut_thms 1
end) i
(* remove the original premises *)
THEN SELECT_GOAL (fn thm =>
let
val n = Logic.count_prems ((Term.strip_all_body o fst o Logic.dest_implies o prop_of) thm, 0)
in
PRIMITIVE (funpow (n div 2) (Seq.hd o weakening_tac 1)) thm
end) i;
(* ------------------------------------------------------------------------- *)
(* cnfx_rewrite_tac: converts all premises of the 'i'-th subgoal to CNF *)
(* (possibly introducing new literals) *)
(* ------------------------------------------------------------------------- *)
(* int -> Tactical.tactic *)
fun cnfx_rewrite_tac i =
(* cut the CNF formulas as new premises *)
METAHYPS (fn prems =>
let
val cnfx_thms = map (fn pr => make_cnfx_thm (theory_of_thm pr) ((HOLogic.dest_Trueprop o prop_of) pr)) prems
val cut_thms = map (fn (th, pr) => cnftac_eq_imp OF [th, pr]) (cnfx_thms ~~ prems)
in
cut_facts_tac cut_thms 1
end) i
(* remove the original premises *)
THEN SELECT_GOAL (fn thm =>
let
val n = Logic.count_prems ((Term.strip_all_body o fst o Logic.dest_implies o prop_of) thm, 0)
in
PRIMITIVE (funpow (n div 2) (Seq.hd o weakening_tac 1)) thm
end) i;
end; (* of structure *)