src/Sequents/LK0.thy
author haftmann
Mon, 08 Jun 2009 08:38:51 +0200
changeset 31483 88210717bfc8
parent 30549 d2d7874648bd
child 35113 1a0c129bb2e0
permissions -rw-r--r--
added generator for char and trivial generator for String.literal

(*  Title:      LK/LK0.thy
    ID:         $Id$
    Author:     Lawrence C Paulson, Cambridge University Computer Laboratory
    Copyright   1993  University of Cambridge

There may be printing problems if a seqent is in expanded normal form
        (eta-expanded, beta-contracted)
*)

header {* Classical First-Order Sequent Calculus *}

theory LK0
imports Sequents
begin

global

classes "term"
defaultsort "term"

consts

  Trueprop       :: "two_seqi"

  True         :: o
  False        :: o
  equal        :: "['a,'a] => o"     (infixl "=" 50)
  Not          :: "o => o"           ("~ _" [40] 40)
  conj         :: "[o,o] => o"       (infixr "&" 35)
  disj         :: "[o,o] => o"       (infixr "|" 30)
  imp          :: "[o,o] => o"       (infixr "-->" 25)
  iff          :: "[o,o] => o"       (infixr "<->" 25)
  The          :: "('a => o) => 'a"  (binder "THE " 10)
  All          :: "('a => o) => o"   (binder "ALL " 10)
  Ex           :: "('a => o) => o"   (binder "EX " 10)

syntax
 "@Trueprop"    :: "two_seqe" ("((_)/ |- (_))" [6,6] 5)

parse_translation {* [("@Trueprop", two_seq_tr "Trueprop")] *}
print_translation {* [("Trueprop", two_seq_tr' "@Trueprop")] *}

abbreviation
  not_equal  (infixl "~=" 50) where
  "x ~= y == ~ (x = y)"

syntax (xsymbols)
  Not           :: "o => o"               ("\<not> _" [40] 40)
  conj          :: "[o, o] => o"          (infixr "\<and>" 35)
  disj          :: "[o, o] => o"          (infixr "\<or>" 30)
  imp           :: "[o, o] => o"          (infixr "\<longrightarrow>" 25)
  iff           :: "[o, o] => o"          (infixr "\<longleftrightarrow>" 25)
  All_binder    :: "[idts, o] => o"       ("(3\<forall>_./ _)" [0, 10] 10)
  Ex_binder     :: "[idts, o] => o"       ("(3\<exists>_./ _)" [0, 10] 10)
  not_equal     :: "['a, 'a] => o"        (infixl "\<noteq>" 50)

syntax (HTML output)
  Not           :: "o => o"               ("\<not> _" [40] 40)
  conj          :: "[o, o] => o"          (infixr "\<and>" 35)
  disj          :: "[o, o] => o"          (infixr "\<or>" 30)
  All_binder    :: "[idts, o] => o"       ("(3\<forall>_./ _)" [0, 10] 10)
  Ex_binder     :: "[idts, o] => o"       ("(3\<exists>_./ _)" [0, 10] 10)
  not_equal     :: "['a, 'a] => o"        (infixl "\<noteq>" 50)

local

axioms

  (*Structural rules: contraction, thinning, exchange [Soren Heilmann] *)

  contRS: "$H |- $E, $S, $S, $F ==> $H |- $E, $S, $F"
  contLS: "$H, $S, $S, $G |- $E ==> $H, $S, $G |- $E"

  thinRS: "$H |- $E, $F ==> $H |- $E, $S, $F"
  thinLS: "$H, $G |- $E ==> $H, $S, $G |- $E"

  exchRS: "$H |- $E, $R, $S, $F ==> $H |- $E, $S, $R, $F"
  exchLS: "$H, $R, $S, $G |- $E ==> $H, $S, $R, $G |- $E"

  cut:   "[| $H |- $E, P;  $H, P |- $E |] ==> $H |- $E"

  (*Propositional rules*)

  basic: "$H, P, $G |- $E, P, $F"

  conjR: "[| $H|- $E, P, $F;  $H|- $E, Q, $F |] ==> $H|- $E, P&Q, $F"
  conjL: "$H, P, Q, $G |- $E ==> $H, P & Q, $G |- $E"

  disjR: "$H |- $E, P, Q, $F ==> $H |- $E, P|Q, $F"
  disjL: "[| $H, P, $G |- $E;  $H, Q, $G |- $E |] ==> $H, P|Q, $G |- $E"

  impR:  "$H, P |- $E, Q, $F ==> $H |- $E, P-->Q, $F"
  impL:  "[| $H,$G |- $E,P;  $H, Q, $G |- $E |] ==> $H, P-->Q, $G |- $E"

  notR:  "$H, P |- $E, $F ==> $H |- $E, ~P, $F"
  notL:  "$H, $G |- $E, P ==> $H, ~P, $G |- $E"

  FalseL: "$H, False, $G |- $E"

  True_def: "True == False-->False"
  iff_def:  "P<->Q == (P-->Q) & (Q-->P)"

  (*Quantifiers*)

  allR:  "(!!x.$H |- $E, P(x), $F) ==> $H |- $E, ALL x. P(x), $F"
  allL:  "$H, P(x), $G, ALL x. P(x) |- $E ==> $H, ALL x. P(x), $G |- $E"

  exR:   "$H |- $E, P(x), $F, EX x. P(x) ==> $H |- $E, EX x. P(x), $F"
  exL:   "(!!x.$H, P(x), $G |- $E) ==> $H, EX x. P(x), $G |- $E"

  (*Equality*)

  refl:  "$H |- $E, a=a, $F"
  subst: "$H(a), $G(a) |- $E(a) ==> $H(b), a=b, $G(b) |- $E(b)"

  (* Reflection *)

  eq_reflection:  "|- x=y ==> (x==y)"
  iff_reflection: "|- P<->Q ==> (P==Q)"

  (*Descriptions*)

  The: "[| $H |- $E, P(a), $F;  !!x.$H, P(x) |- $E, x=a, $F |] ==>
          $H |- $E, P(THE x. P(x)), $F"

constdefs
  If :: "[o, 'a, 'a] => 'a"   ("(if (_)/ then (_)/ else (_))" 10)
   "If(P,x,y) == THE z::'a. (P --> z=x) & (~P --> z=y)"


(** Structural Rules on formulas **)

(*contraction*)

lemma contR: "$H |- $E, P, P, $F ==> $H |- $E, P, $F"
  by (rule contRS)

lemma contL: "$H, P, P, $G |- $E ==> $H, P, $G |- $E"
  by (rule contLS)

(*thinning*)

lemma thinR: "$H |- $E, $F ==> $H |- $E, P, $F"
  by (rule thinRS)

lemma thinL: "$H, $G |- $E ==> $H, P, $G |- $E"
  by (rule thinLS)

(*exchange*)

lemma exchR: "$H |- $E, Q, P, $F ==> $H |- $E, P, Q, $F"
  by (rule exchRS)

lemma exchL: "$H, Q, P, $G |- $E ==> $H, P, Q, $G |- $E"
  by (rule exchLS)

ML {*
(*Cut and thin, replacing the right-side formula*)
fun cutR_tac ctxt s i =
  res_inst_tac ctxt [(("P", 0), s) ] @{thm cut} i  THEN  rtac @{thm thinR} i

(*Cut and thin, replacing the left-side formula*)
fun cutL_tac ctxt s i =
  res_inst_tac ctxt [(("P", 0), s)] @{thm cut} i  THEN  rtac @{thm thinL} (i+1)
*}


(** If-and-only-if rules **)
lemma iffR: 
    "[| $H,P |- $E,Q,$F;  $H,Q |- $E,P,$F |] ==> $H |- $E, P <-> Q, $F"
  apply (unfold iff_def)
  apply (assumption | rule conjR impR)+
  done

lemma iffL: 
    "[| $H,$G |- $E,P,Q;  $H,Q,P,$G |- $E |] ==> $H, P <-> Q, $G |- $E"
  apply (unfold iff_def)
  apply (assumption | rule conjL impL basic)+
  done

lemma iff_refl: "$H |- $E, (P <-> P), $F"
  apply (rule iffR basic)+
  done

lemma TrueR: "$H |- $E, True, $F"
  apply (unfold True_def)
  apply (rule impR)
  apply (rule basic)
  done

(*Descriptions*)
lemma the_equality:
  assumes p1: "$H |- $E, P(a), $F"
    and p2: "!!x. $H, P(x) |- $E, x=a, $F"
  shows "$H |- $E, (THE x. P(x)) = a, $F"
  apply (rule cut)
   apply (rule_tac [2] p2)
  apply (rule The, rule thinR, rule exchRS, rule p1)
  apply (rule thinR, rule exchRS, rule p2)
  done


(** Weakened quantifier rules.  Incomplete, they let the search terminate.**)

lemma allL_thin: "$H, P(x), $G |- $E ==> $H, ALL x. P(x), $G |- $E"
  apply (rule allL)
  apply (erule thinL)
  done

lemma exR_thin: "$H |- $E, P(x), $F ==> $H |- $E, EX x. P(x), $F"
  apply (rule exR)
  apply (erule thinR)
  done

(*The rules of LK*)

ML {*
val prop_pack = empty_pack add_safes
                [thm "basic", thm "refl", thm "TrueR", thm "FalseL",
                 thm "conjL", thm "conjR", thm "disjL", thm "disjR", thm "impL", thm "impR",
                 thm "notL", thm "notR", thm "iffL", thm "iffR"];

val LK_pack = prop_pack add_safes   [thm "allR", thm "exL"]
                        add_unsafes [thm "allL_thin", thm "exR_thin", thm "the_equality"];

val LK_dup_pack = prop_pack add_safes   [thm "allR", thm "exL"]
                            add_unsafes [thm "allL", thm "exR", thm "the_equality"];


local
  val thinR = thm "thinR"
  val thinL = thm "thinL"
  val cut = thm "cut"
in

fun lemma_tac th i =
    rtac (thinR RS cut) i THEN REPEAT (rtac thinL i) THEN rtac th i;

end;
*}

method_setup fast_prop =
  {* Scan.succeed (K (SIMPLE_METHOD' (fast_tac prop_pack))) *}
  "propositional reasoning"

method_setup fast =
  {* Scan.succeed (K (SIMPLE_METHOD' (fast_tac LK_pack))) *}
  "classical reasoning"

method_setup fast_dup =
  {* Scan.succeed (K (SIMPLE_METHOD' (fast_tac LK_dup_pack))) *}
  "classical reasoning"

method_setup best =
  {* Scan.succeed (K (SIMPLE_METHOD' (best_tac LK_pack))) *}
  "classical reasoning"

method_setup best_dup =
  {* Scan.succeed (K (SIMPLE_METHOD' (best_tac LK_dup_pack))) *}
  "classical reasoning"


lemma mp_R:
  assumes major: "$H |- $E, $F, P --> Q"
    and minor: "$H |- $E, $F, P"
  shows "$H |- $E, Q, $F"
  apply (rule thinRS [THEN cut], rule major)
  apply (tactic "step_tac LK_pack 1")
  apply (rule thinR, rule minor)
  done

lemma mp_L:
  assumes major: "$H, $G |- $E, P --> Q"
    and minor: "$H, $G, Q |- $E"
  shows "$H, P, $G |- $E"
  apply (rule thinL [THEN cut], rule major)
  apply (tactic "step_tac LK_pack 1")
  apply (rule thinL, rule minor)
  done


(** Two rules to generate left- and right- rules from implications **)

lemma R_of_imp:
  assumes major: "|- P --> Q"
    and minor: "$H |- $E, $F, P"
  shows "$H |- $E, Q, $F"
  apply (rule mp_R)
   apply (rule_tac [2] minor)
  apply (rule thinRS, rule major [THEN thinLS])
  done

lemma L_of_imp:
  assumes major: "|- P --> Q"
    and minor: "$H, $G, Q |- $E"
  shows "$H, P, $G |- $E"
  apply (rule mp_L)
   apply (rule_tac [2] minor)
  apply (rule thinRS, rule major [THEN thinLS])
  done

(*Can be used to create implications in a subgoal*)
lemma backwards_impR:
  assumes prem: "$H, $G |- $E, $F, P --> Q"
  shows "$H, P, $G |- $E, Q, $F"
  apply (rule mp_L)
   apply (rule_tac [2] basic)
  apply (rule thinR, rule prem)
  done

lemma conjunct1: "|-P&Q ==> |-P"
  apply (erule thinR [THEN cut])
  apply fast
  done

lemma conjunct2: "|-P&Q ==> |-Q"
  apply (erule thinR [THEN cut])
  apply fast
  done

lemma spec: "|- (ALL x. P(x)) ==> |- P(x)"
  apply (erule thinR [THEN cut])
  apply fast
  done


(** Equality **)

lemma sym: "|- a=b --> b=a"
  by (tactic {* safe_tac (LK_pack add_safes [thm "subst"]) 1 *})

lemma trans: "|- a=b --> b=c --> a=c"
  by (tactic {* safe_tac (LK_pack add_safes [thm "subst"]) 1 *})

(* Symmetry of equality in hypotheses *)
lemmas symL = sym [THEN L_of_imp, standard]

(* Symmetry of equality in hypotheses *)
lemmas symR = sym [THEN R_of_imp, standard]

lemma transR: "[| $H|- $E, $F, a=b;  $H|- $E, $F, b=c |] ==> $H|- $E, a=c, $F"
  by (rule trans [THEN R_of_imp, THEN mp_R])

(* Two theorms for rewriting only one instance of a definition:
   the first for definitions of formulae and the second for terms *)

lemma def_imp_iff: "(A == B) ==> |- A <-> B"
  apply unfold
  apply (rule iff_refl)
  done

lemma meta_eq_to_obj_eq: "(A == B) ==> |- A = B"
  apply unfold
  apply (rule refl)
  done


(** if-then-else rules **)

lemma if_True: "|- (if True then x else y) = x"
  unfolding If_def by fast

lemma if_False: "|- (if False then x else y) = y"
  unfolding If_def by fast

lemma if_P: "|- P ==> |- (if P then x else y) = x"
  apply (unfold If_def)
  apply (erule thinR [THEN cut])
  apply fast
  done

lemma if_not_P: "|- ~P ==> |- (if P then x else y) = y";
  apply (unfold If_def)
  apply (erule thinR [THEN cut])
  apply fast
  done

end