src/Provers/induct_method.ML

replaced calls to PropLogic.defcnf by PropLogic.auxcnf

(*  Title:      Provers/induct_method.ML
    ID:         $Id$
    Author:     Markus Wenzel, TU Muenchen

Proof by cases and induction on sets and types.
*)

signature INDUCT_METHOD_DATA =
sig
  val dest_concls: term -> term list
  val cases_default: thm
  val local_impI: thm
  val conjI: thm
  val atomize: thm list
  val rulify1: thm list
  val rulify2: thm list
  val localize: thm list
end;

signature INDUCT_METHOD =
sig
  val cases_tac: Proof.context -> bool -> term option list list -> thm option ->
    thm list -> int -> RuleCases.tactic
  val induct_tac: Proof.context -> bool -> term option list list ->
    thm option -> thm list -> int -> RuleCases.tactic
  val setup: (theory -> theory) list
end;

functor InductMethodFun(Data: INDUCT_METHOD_DATA): INDUCT_METHOD =
struct


(** misc utils **)

(* align lists *)

fun align_left msg xs ys =
  let val m = length xs and n = length ys
  in if m < n then raise ERROR_MESSAGE msg else (Library.take (n, xs) ~~ ys) end;

fun align_right msg xs ys =
  let val m = length xs and n = length ys
  in if m < n then raise ERROR_MESSAGE msg else (Library.drop (m - n, xs) ~~ ys) end;


(* prep_inst *)

fun prep_inst align cert tune (tm, ts) =
  let
    fun prep_var (x, SOME t) =
          let
            val cx = cert x;
            val {T = xT, sign, ...} = Thm.rep_cterm cx;
            val ct = cert (tune t);
          in
            if Sign.typ_instance sign (#T (Thm.rep_cterm ct), xT) then SOME (cx, ct)
            else raise ERROR_MESSAGE (Pretty.string_of (Pretty.block
             [Pretty.str "Ill-typed instantiation:", Pretty.fbrk,
              Display.pretty_cterm ct, Pretty.str " ::", Pretty.brk 1,
              Display.pretty_ctyp (#T (Thm.crep_cterm ct))]))
          end
      | prep_var (_, NONE) = NONE;
    val xs = InductAttrib.vars_of tm;
  in
    align "Rule has fewer variables than instantiations given" xs ts
    |> List.mapPartial prep_var
  end;



(** cases method **)

(*
  rule selection scheme:
          cases         - classical case split
    <x:A> cases ...     - set cases
          cases t       - type cases
    ...   cases ... R   - explicit rule
*)

local

fun resolveq_cases_tac make ruleq i st =
  ruleq |> Seq.map (fn (rule, (cases, facts)) =>
    (Method.insert_tac facts THEN' Tactic.rtac rule) i st
    |> Seq.map (rpair (make (Thm.sign_of_thm rule, Thm.prop_of rule) cases)))
  |> Seq.flat;

fun find_casesT ctxt ((SOME t :: _) :: _) = InductAttrib.find_casesT ctxt (fastype_of t)
  | find_casesT _ _ = [];

fun find_casesS ctxt (fact :: _) = InductAttrib.find_casesS ctxt fact
  | find_casesS _ _ = [];

in

fun cases_tac ctxt is_open insts opt_rule facts =
  let
    val sg = ProofContext.sign_of ctxt;
    val cert = Thm.cterm_of sg;

    fun inst_rule r =
      if null insts then RuleCases.add r
      else (align_left "Rule has fewer premises than arguments given" (Thm.prems_of r) insts
        |> (List.concat o map (prep_inst align_left cert I))
        |> Drule.cterm_instantiate) r |> rpair (RuleCases.get r);

    val ruleq =
      (case opt_rule of
        NONE =>
          let val rules = find_casesS ctxt facts @ find_casesT ctxt insts @ [Data.cases_default] in
            Method.trace ctxt rules;
            Seq.flat (Seq.map (Seq.try inst_rule) (Seq.of_list rules))
          end
      | SOME r => Seq.single (inst_rule r));

    fun prep_rule (th, (cases, n)) = Seq.map (apsnd (rpair (Library.drop (n, facts))) o rpair cases)
      (Method.multi_resolves (Library.take (n, facts)) [th]);
  in resolveq_cases_tac (RuleCases.make is_open NONE) (Seq.flat (Seq.map prep_rule ruleq)) end;

val cases_meth = Method.METHOD_CASES o ((Seq.DETERM o HEADGOAL) oo
  (fn (ctxt, (is_open, (insts, opt_rule))) => cases_tac ctxt is_open insts opt_rule));

end;



(** induct method **)

(*
  rule selection scheme:
    <x:A> induct ...     - set induction
          induct x       - type induction
    ...   induct ... R   - explicit rule
*)

local


(* atomize and rulify *)

fun atomize_term sg =
  ObjectLogic.drop_judgment sg o MetaSimplifier.rewrite_term sg Data.atomize [];

fun rulified_term thm =
  let val sg = Thm.sign_of_thm thm in
    Thm.prop_of thm
    |> MetaSimplifier.rewrite_term sg Data.rulify1 []
    |> MetaSimplifier.rewrite_term sg Data.rulify2 []
    |> pair sg
  end;

val atomize_tac = Tactic.rewrite_goal_tac Data.atomize;

val rulify_tac =
  Tactic.rewrite_goal_tac Data.rulify1 THEN'
  Tactic.rewrite_goal_tac Data.rulify2 THEN'
  Tactic.norm_hhf_tac;

val localize = Tactic.norm_hhf_rule o Tactic.simplify false Data.localize;


(* imp_intr --- limited to atomic prems *)

fun imp_intr i raw_th =
  let
    val th = Thm.permute_prems (i - 1) 1 raw_th;
    val cprems = Drule.cprems_of th;
    val As = Library.take (length cprems - 1, cprems);
    val C = Thm.cterm_of (Thm.sign_of_thm th) (Var (("C", #maxidx (Thm.rep_thm th) + 1), propT));
    val dummy_st = Drule.mk_triv_goal (Drule.list_implies (As, C));
  in th COMP Thm.lift_rule (dummy_st, 1) Data.local_impI end;


(* join multi-rules *)

val eq_prems = curry (Term.aconvs o pairself Thm.prems_of);

fun join_rules [] = []
  | join_rules [th] = [th]
  | join_rules (rules as r :: rs) =
      if not (forall (eq_prems r) rs) then []
      else
        let
          val th :: ths = map Drule.freeze_all rules;
          val cprems = Drule.cprems_of th;
          val asms = map Thm.assume cprems;
        in
          [foldr1 (fn (x, x') => [x, x'] MRS Data.conjI)
            (map (fn x => Drule.implies_elim_list x asms) (th :: ths))
          |> Drule.implies_intr_list cprems
          |> Drule.standard'
          |> RuleCases.save r]
        end;


(* divinate rule instantiation (cannot handle pending goal parameters) *)

fun dest_env sign (env as Envir.Envir {iTs, ...}) =
  let
    val pairs = Envir.alist_of env;
    val ts = map (Thm.cterm_of sign o Envir.norm_term env o #2 o #2) pairs;
    val xs = map2 (Thm.cterm_of sign o Var) (map #1 pairs, map (#T o Thm.rep_cterm) ts);
    val cert = Thm.ctyp_of sign;
  in (map (fn (ixn, (S, T)) => (cert (TVar (ixn, S)), cert T)) (Vartab.dest iTs), xs ~~ ts) end;

fun divinate_inst rule i st =
  let
    val {sign, maxidx, ...} = Thm.rep_thm st;
    val goal = List.nth (Thm.prems_of st, i - 1);  (*exception Subscript*)
    val params = rev (rename_wrt_term goal (Logic.strip_params goal));  (*as they are printed :-*)
  in
    if not (null params) then
      (warning ("Cannot determine rule instantiation due to pending parameter(s): " ^
        commas (map (Sign.string_of_term sign o Syntax.mark_boundT) params));
      Seq.single rule)
    else
      let
        val rule' = Thm.incr_indexes (maxidx + 1) rule;
        val concl = Logic.strip_assums_concl goal;
      in
        Unify.smash_unifiers (sign, Envir.empty (#maxidx (Thm.rep_thm rule')),
          [(Thm.concl_of rule', concl)])
        |> Seq.map (fn env => Drule.instantiate (dest_env sign env) rule')
      end
  end handle Subscript => Seq.empty;


(* compose tactics with cases *)

fun internalize k th = if k > 0 then internalize (k - 1) (imp_intr k th) else th;

fun resolveq_cases_tac' make is_open ruleq i st =
  ruleq |> Seq.map (fn (rule, (cases, k, more_facts)) => st
    |> (Method.insert_tac more_facts THEN' atomize_tac) i
    |> Seq.map (fn st' => divinate_inst (internalize k rule) i st' |> Seq.map (fn rule' =>
          st' |> Tactic.rtac rule' i
          |> Seq.map (rpair (make is_open (SOME (Thm.prop_of rule')) (rulified_term rule') cases)))
      |> Seq.flat)
    |> Seq.flat)
  |> Seq.flat;

infix 1 THEN_ALL_NEW_CASES;

fun (tac1 THEN_ALL_NEW_CASES tac2) i st =
  st |> Seq.THEN (tac1 i, (fn (st', cases) =>
    Seq.map (rpair cases) (Seq.INTERVAL tac2 i (i + nprems_of st' - nprems_of st) st')));


(* find rules *)

(* rename all outermost !!-bound vars of type T in all premises of thm to x,
   possibly indexed to avoid clashes *)
fun rename [[SOME(Free(x,Type(T,_)))]] thm =
  let
    fun index i [] = []
      | index i (y::ys) = if x=y then x^string_of_int i :: index (i+1) ys
                          else y :: index i ys;
    fun rename_params [] = []
      | rename_params ((y,Type(U,_))::ys) =
          (if U=T then x else y)::rename_params ys
      | rename_params ((y,_)::ys) = y::rename_params ys;
    fun rename_asm (A:term):term = 
      let val xs = rename_params (Logic.strip_params A)
          val xs' = case List.filter (equal x) xs of
                      [] => xs | [_] => xs | _ => index 1 xs
      in Logic.list_rename_params (xs',A) end;
    fun rename_prop (p:term) =
      let val (As,C) = Logic.strip_horn p
      in Logic.list_implies(map rename_asm As, C) end;
    val cp' = cterm_fun rename_prop (cprop_of thm);
    val thm' = equal_elim (reflexive cp') thm
  in Thm.put_name_tags (Thm.get_name_tags thm) thm' end
  | rename _ thm = thm;

fun find_inductT ctxt insts =
  foldr multiply [[]] (insts |> List.mapPartial (fn [] => NONE | ts => List.last ts)
    |> map (InductAttrib.find_inductT ctxt o fastype_of))
  |> map join_rules |> List.concat |> map (rename insts);

fun find_inductS ctxt (fact :: _) = InductAttrib.find_inductS ctxt fact
  | find_inductS _ _ = [];

in

(* main tactic *)

fun induct_tac ctxt is_open insts opt_rule facts =
  let
    val sg = ProofContext.sign_of ctxt;
    val cert = Thm.cterm_of sg;

    fun rule_versions r = Seq.cons (r, Seq.filter (not o curry Thm.eq_thm r)
        (Seq.make (fn () => SOME (localize r, Seq.empty))))
      |> Seq.map (rpair (RuleCases.get r));

    val inst_rule = apfst (fn r =>
      if null insts then r
      else (align_right "Rule has fewer conclusions than arguments given"
          (Data.dest_concls (Thm.concl_of r)) insts
        |> (List.concat o map (prep_inst align_right cert (atomize_term sg)))
        |> Drule.cterm_instantiate) r);

    val ruleq =
      (case opt_rule of
        NONE =>
          let val rules = find_inductS ctxt facts @ find_inductT ctxt insts in
            conditional (null rules) (fn () => error "Unable to figure out induct rule");
            Method.trace ctxt rules;
            rules |> Seq.THEN (Seq.of_list, Seq.THEN (rule_versions, Seq.try inst_rule))
          end
      | SOME r => r |> Seq.THEN (rule_versions, Seq.single o inst_rule));

    fun prep_rule (th, (cases, n)) =
      Seq.map (rpair (cases, n - length facts, Library.drop (n, facts)))
        (Method.multi_resolves (Library.take (n, facts)) [th]);
    val tac = resolveq_cases_tac' RuleCases.make is_open (Seq.flat (Seq.map prep_rule ruleq));
  in tac THEN_ALL_NEW_CASES rulify_tac end;

val induct_meth = Method.RAW_METHOD_CASES o ((Seq.DETERM o HEADGOAL) oo
  (fn (ctxt, (is_open, (insts, opt_rule))) => induct_tac ctxt is_open insts opt_rule));

end;



(** concrete syntax **)

val openN = "open";
val ruleN = "rule";
val ofN = "of";

local

fun named_rule k arg get =
  Scan.lift (Args.$$$ k -- Args.colon) |-- arg :-- (fn name => Scan.peek (fn ctxt =>
    (case get ctxt name of SOME x => Scan.succeed x
    | NONE => error ("No rule for " ^ k ^ " " ^ quote name)))) >> #2;

fun rule get_type get_set =
  named_rule InductAttrib.typeN Args.local_tyname get_type ||
  named_rule InductAttrib.setN Args.local_const get_set ||
  Scan.lift (Args.$$$ ruleN -- Args.colon) |-- Attrib.local_thm;

val cases_rule = rule InductAttrib.lookup_casesT InductAttrib.lookup_casesS;
val induct_rule = rule InductAttrib.lookup_inductT InductAttrib.lookup_inductS;

val kind_inst =
  (Args.$$$ InductAttrib.typeN || Args.$$$ InductAttrib.setN || Args.$$$ ruleN || Args.$$$ ofN)
    -- Args.colon;
val term = Scan.unless (Scan.lift kind_inst) Args.local_term;
val term_dummy = Scan.unless (Scan.lift kind_inst)
  (Scan.lift (Args.$$$ "_") >> K NONE || Args.local_term >> SOME);

val instss = Args.and_list (Scan.repeat term_dummy);

in

val cases_args = Method.syntax (Args.mode openN -- (instss -- Scan.option cases_rule));
val induct_args = Method.syntax (Args.mode openN -- (instss -- Scan.option induct_rule));

end;



(** theory setup **)

val setup =
  [Method.add_methods
    [(InductAttrib.casesN, cases_meth oo cases_args, "case analysis on types or sets"),
     (InductAttrib.inductN, induct_meth oo induct_args, "induction on types or sets")]];

end;