Theory Semilat

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theory Semilat
imports While_Combinator
begin

(*  Title:      HOL/MicroJava/BV/Semilat.thy
    ID:         $Id: Semilat.thy,v 1.17 2005/06/17 14:13:08 haftmann Exp $
    Author:     Tobias Nipkow
    Copyright   2000 TUM

Semilattices
*)

header {* 
  \chapter{Bytecode Verifier}\label{cha:bv}
  \isaheader{Semilattices} 
*}

theory Semilat imports While_Combinator begin

types 'a ord    = "'a => 'a => bool"
      'a binop  = "'a => 'a => 'a"
      'a sl     = "'a set * 'a ord * 'a binop"

consts
 "@lesub"   :: "'a => 'a ord => 'a => bool" ("(_ /<='__ _)" [50, 1000, 51] 50)
 "@lesssub" :: "'a => 'a ord => 'a => bool" ("(_ /<'__ _)" [50, 1000, 51] 50)
defs
lesub_def:   "x <=_r y == r x y"
lesssub_def: "x <_r y  == x <=_r y & x ~= y"

syntax (xsymbols)
 "@lesub" :: "'a => 'a ord => 'a => bool" ("(_ /≤_ _)" [50, 1000, 51] 50)

consts
 "@plussub" :: "'a => ('a => 'b => 'c) => 'b => 'c" ("(_ /+'__ _)" [65, 1000, 66] 65)
defs
plussub_def: "x +_f y == f x y"

syntax (xsymbols)
 "@plussub" :: "'a => ('a => 'b => 'c) => 'b => 'c" ("(_ /+_ _)" [65, 1000, 66] 65)

syntax (xsymbols)
 "@plussub" :: "'a => ('a => 'b => 'c) => 'b => 'c" ("(_ /\<squnion>_ _)" [65, 1000, 66] 65)


constdefs
 ord :: "('a*'a)set => 'a ord"
"ord r == %x y. (x,y):r"

 order :: "'a ord => bool"
"order r == (!x. x <=_r x) &
            (!x y. x <=_r y & y <=_r x --> x=y) &
            (!x y z. x <=_r y & y <=_r z --> x <=_r z)"

 acc :: "'a ord => bool"
"acc r == wf{(y,x) . x <_r y}"

 top :: "'a ord => 'a => bool"
"top r T == !x. x <=_r T"

 closed :: "'a set => 'a binop => bool"
"closed A f == !x:A. !y:A. x +_f y : A"

 semilat :: "'a sl => bool"
"semilat == %(A,r,f). order r & closed A f &
                (!x:A. !y:A. x <=_r x +_f y)  &
                (!x:A. !y:A. y <=_r x +_f y)  &
                (!x:A. !y:A. !z:A. x <=_r z & y <=_r z --> x +_f y <=_r z)"

 is_ub :: "('a*'a)set => 'a => 'a => 'a => bool"
"is_ub r x y u == (x,u):r & (y,u):r"

 is_lub :: "('a*'a)set => 'a => 'a => 'a => bool"
"is_lub r x y u == is_ub r x y u & (!z. is_ub r x y z --> (u,z):r)"

 some_lub :: "('a*'a)set => 'a => 'a => 'a"
"some_lub r x y == SOME z. is_lub r x y z";

locale (open) semilat =
  fixes A :: "'a set"
    and r :: "'a ord"
    and f :: "'a binop"
  assumes semilat: "semilat(A,r,f)"

lemma order_refl [simp, intro]:
  "order r ==> x <=_r x";
  by (simp add: order_def)

lemma order_antisym:
  "[| order r; x <=_r y; y <=_r x |] ==> x = y"
apply (unfold order_def)
apply (simp (no_asm_simp))
done

lemma order_trans:
   "[| order r; x <=_r y; y <=_r z |] ==> x <=_r z"
apply (unfold order_def)
apply blast
done 

lemma order_less_irrefl [intro, simp]:
   "order r ==> ~ x <_r x"
apply (unfold order_def lesssub_def)
apply blast
done 

lemma order_less_trans:
  "[| order r; x <_r y; y <_r z |] ==> x <_r z"
apply (unfold order_def lesssub_def)
apply blast
done 

lemma topD [simp, intro]:
  "top r T ==> x <=_r T"
  by (simp add: top_def)

lemma top_le_conv [simp]:
  "[| order r; top r T |] ==> (T <=_r x) = (x = T)"
  by (blast intro: order_antisym)

lemma semilat_Def:
"semilat(A,r,f) == order r & closed A f & 
                 (!x:A. !y:A. x <=_r x +_f y) & 
                 (!x:A. !y:A. y <=_r x +_f y) & 
                 (!x:A. !y:A. !z:A. x <=_r z & y <=_r z --> x +_f y <=_r z)"
apply (unfold semilat_def split_conv [THEN eq_reflection])
apply (rule refl [THEN eq_reflection])
done

lemma (in semilat) orderI [simp, intro]:
  "order r"
  by (insert semilat) (simp add: semilat_Def)

lemma (in semilat) closedI [simp, intro]:
  "closed A f"
  by (insert semilat) (simp add: semilat_Def)

lemma closedD:
  "[| closed A f; x:A; y:A |] ==> x +_f y : A"
  by (unfold closed_def) blast

lemma closed_UNIV [simp]: "closed UNIV f"
  by (simp add: closed_def)


lemma (in semilat) closed_f [simp, intro]:
  "[|x:A; y:A|]  ==> x +_f y : A"
  by (simp add: closedD [OF closedI])

lemma (in semilat) refl_r [intro, simp]:
  "x <=_r x"
  by simp

lemma (in semilat) antisym_r [intro?]:
  "[| x <=_r y; y <=_r x |] ==> x = y"
  by (rule order_antisym) auto
  
lemma (in semilat) trans_r [trans, intro?]:
  "[|x <=_r y; y <=_r z|] ==> x <=_r z"
  by (auto intro: order_trans)    
  

lemma (in semilat) ub1 [simp, intro?]:
  "[| x:A; y:A |] ==> x <=_r x +_f y"
  by (insert semilat) (unfold semilat_Def, simp)

lemma (in semilat) ub2 [simp, intro?]:
  "[| x:A; y:A |] ==> y <=_r x +_f y"
  by (insert semilat) (unfold semilat_Def, simp)

lemma (in semilat) lub [simp, intro?]:
 "[| x <=_r z; y <=_r z; x:A; y:A; z:A |] ==> x +_f y <=_r z";
  by (insert semilat) (unfold semilat_Def, simp)


lemma (in semilat) plus_le_conv [simp]:
  "[| x:A; y:A; z:A |] ==> (x +_f y <=_r z) = (x <=_r z & y <=_r z)"
  by (blast intro: ub1 ub2 lub order_trans)

lemma (in semilat) le_iff_plus_unchanged:
  "[| x:A; y:A |] ==> (x <=_r y) = (x +_f y = y)"
apply (rule iffI)
 apply (blast intro: antisym_r refl_r lub ub2)
apply (erule subst)
apply simp
done

lemma (in semilat) le_iff_plus_unchanged2:
  "[| x:A; y:A |] ==> (x <=_r y) = (y +_f x = y)"
apply (rule iffI)
 apply (blast intro: order_antisym lub order_refl ub1)
apply (erule subst)
apply simp
done 


lemma (in semilat) plus_assoc [simp]:
  assumes a: "a ∈ A" and b: "b ∈ A" and c: "c ∈ A"
  shows "a +_f (b +_f c) = a +_f b +_f c"
proof -
  from a b have ab: "a +_f b ∈ A" ..
  from this c have abc: "(a +_f b) +_f c ∈ A" ..
  from b c have bc: "b +_f c ∈ A" ..
  from a this have abc': "a +_f (b +_f c) ∈ A" ..

  show ?thesis
  proof    
    show "a +_f (b +_f c) <=_r (a +_f b) +_f c"
    proof -
      from a b have "a <=_r a +_f b" .. 
      also from ab c have "… <=_r … +_f c" ..
      finally have "a<": "a <=_r (a +_f b) +_f c" .
      from a b have "b <=_r a +_f b" ..
      also from ab c have "… <=_r … +_f c" ..
      finally have "b<": "b <=_r (a +_f b) +_f c" .
      from ab c have "c<": "c <=_r (a +_f b) +_f c" ..    
      from "b<" "c<" b c abc have "b +_f c <=_r (a +_f b) +_f c" ..
      from "a<" this a bc abc show ?thesis ..
    qed
    show "(a +_f b) +_f c <=_r a +_f (b +_f c)" 
    proof -
      from b c have "b <=_r b +_f c" .. 
      also from a bc have "… <=_r a +_f …" ..
      finally have "b<": "b <=_r a +_f (b +_f c)" .
      from b c have "c <=_r b +_f c" ..
      also from a bc have "… <=_r a +_f …" ..
      finally have "c<": "c <=_r a +_f (b +_f c)" .
      from a bc have "a<": "a <=_r a +_f (b +_f c)" ..
      from "a<" "b<" a b abc' have "a +_f b <=_r a +_f (b +_f c)" ..
      from this "c<" ab c abc' show ?thesis ..
    qed
  qed
qed

lemma (in semilat) plus_com_lemma:
  "[|a ∈ A; b ∈ A|] ==> a +_f b <=_r b +_f a"
proof -
  assume a: "a ∈ A" and b: "b ∈ A"  
  from b a have "a <=_r b +_f a" .. 
  moreover from b a have "b <=_r b +_f a" ..
  moreover note a b
  moreover from b a have "b +_f a ∈ A" ..
  ultimately show ?thesis ..
qed

lemma (in semilat) plus_commutative:
  "[|a ∈ A; b ∈ A|] ==> a +_f b = b +_f a"
by(blast intro: order_antisym plus_com_lemma)

lemma is_lubD:
  "is_lub r x y u ==> is_ub r x y u & (!z. is_ub r x y z --> (u,z):r)"
  by (simp add: is_lub_def)

lemma is_ubI:
  "[| (x,u) : r; (y,u) : r |] ==> is_ub r x y u"
  by (simp add: is_ub_def)

lemma is_ubD:
  "is_ub r x y u ==> (x,u) : r & (y,u) : r"
  by (simp add: is_ub_def)


lemma is_lub_bigger1 [iff]:  
  "is_lub (r^* ) x y y = ((x,y):r^* )"
apply (unfold is_lub_def is_ub_def)
apply blast
done

lemma is_lub_bigger2 [iff]:
  "is_lub (r^* ) x y x = ((y,x):r^* )"
apply (unfold is_lub_def is_ub_def)
apply blast 
done

lemma extend_lub:
  "[| single_valued r; is_lub (r^* ) x y u; (x',x) : r |] 
  ==> EX v. is_lub (r^* ) x' y v"
apply (unfold is_lub_def is_ub_def)
apply (case_tac "(y,x) : r^*")
 apply (case_tac "(y,x') : r^*")
  apply blast
 apply (blast elim: converse_rtranclE dest: single_valuedD)
apply (rule exI)
apply (rule conjI)
 apply (blast intro: converse_rtrancl_into_rtrancl dest: single_valuedD)
apply (blast intro: rtrancl_into_rtrancl converse_rtrancl_into_rtrancl 
             elim: converse_rtranclE dest: single_valuedD)
done

lemma single_valued_has_lubs [rule_format]:
  "[| single_valued r; (x,u) : r^* |] ==> (!y. (y,u) : r^* --> 
  (EX z. is_lub (r^* ) x y z))"
apply (erule converse_rtrancl_induct)
 apply clarify
 apply (erule converse_rtrancl_induct)
  apply blast
 apply (blast intro: converse_rtrancl_into_rtrancl)
apply (blast intro: extend_lub)
done

lemma some_lub_conv:
  "[| acyclic r; is_lub (r^* ) x y u |] ==> some_lub (r^* ) x y = u"
apply (unfold some_lub_def is_lub_def)
apply (rule someI2)
 apply assumption
apply (blast intro: antisymD dest!: acyclic_impl_antisym_rtrancl)
done

lemma is_lub_some_lub:
  "[| single_valued r; acyclic r; (x,u):r^*; (y,u):r^* |] 
  ==> is_lub (r^* ) x y (some_lub (r^* ) x y)";
  by (fastsimp dest: single_valued_has_lubs simp add: some_lub_conv)

subsection{*An executable lub-finder*}

constdefs
 exec_lub :: "('a * 'a) set => ('a => 'a) => 'a binop"
"exec_lub r f x y == while (λz. (x,z) ∉ r*) f y"


lemma acyclic_single_valued_finite:
 "[|acyclic r; single_valued r; (x,y) ∈ r*|]
  ==> finite (r ∩ {a. (x, a) ∈ r*} × {b. (b, y) ∈ r*})"
apply(erule converse_rtrancl_induct)
 apply(rule_tac B = "{}" in finite_subset)
  apply(simp only:acyclic_def)
  apply(blast intro:rtrancl_into_trancl2 rtrancl_trancl_trancl)
 apply simp
apply(rename_tac x x')
apply(subgoal_tac "r ∩ {a. (x,a) ∈ r*} × {b. (b,y) ∈ r*} =
                   insert (x,x') (r ∩ {a. (x', a) ∈ r*} × {b. (b, y) ∈ r*})")
 apply simp
apply(blast intro:converse_rtrancl_into_rtrancl
            elim:converse_rtranclE dest:single_valuedD)
done


lemma exec_lub_conv:
  "[| acyclic r; !x y. (x,y) ∈ r --> f x = y; is_lub (r*) x y u |] ==>
  exec_lub r f x y = u";
apply(unfold exec_lub_def)
apply(rule_tac P = "λz. (y,z) ∈ r* ∧ (z,u) ∈ r*" and
               r = "(r ∩ {(a,b). (y,a) ∈ r* ∧ (b,u) ∈ r*})^-1" in while_rule)
    apply(blast dest: is_lubD is_ubD)
   apply(erule conjE)
   apply(erule_tac z = u in converse_rtranclE)
    apply(blast dest: is_lubD is_ubD)
   apply(blast dest:rtrancl_into_rtrancl)
  apply(rename_tac s)
  apply(subgoal_tac "is_ub (r*) x y s")
   prefer 2; apply(simp add:is_ub_def)
  apply(subgoal_tac "(u, s) ∈ r*")
   prefer 2; apply(blast dest:is_lubD)
  apply(erule converse_rtranclE)
   apply blast
  apply(simp only:acyclic_def)
  apply(blast intro:rtrancl_into_trancl2 rtrancl_trancl_trancl)
 apply(rule finite_acyclic_wf)
  apply simp
  apply(erule acyclic_single_valued_finite)
   apply(blast intro:single_valuedI)
  apply(simp add:is_lub_def is_ub_def)
 apply simp
 apply(erule acyclic_subset)
 apply blast
apply simp
apply(erule conjE)
apply(erule_tac z = u in converse_rtranclE)
 apply(blast dest: is_lubD is_ubD)
apply(blast dest:rtrancl_into_rtrancl)
done

lemma is_lub_exec_lub:
  "[| single_valued r; acyclic r; (x,u):r^*; (y,u):r^*; !x y. (x,y) ∈ r --> f x = y |]
  ==> is_lub (r^* ) x y (exec_lub r f x y)"
  by (fastsimp dest: single_valued_has_lubs simp add: exec_lub_conv)

end

lemma order_refl:

  order r ==> x <=_r x

lemma order_antisym:

  [| order r; x <=_r y; y <=_r x |] ==> x = y

lemma order_trans:

  [| order r; x <=_r y; y <=_r z |] ==> x <=_r z

lemma order_less_irrefl:

  order r ==> ¬ x <_r x

lemma order_less_trans:

  [| order r; x <_r y; y <_r z |] ==> x <_r z

lemma topD:

  top r T ==> x <=_r T

lemma top_le_conv:

  [| order r; top r T |] ==> (T <=_r x) = (x = T)

lemma semilat_Def:

  semilat (A, r, f) ==
  order r ∧
  closed A f ∧
  (∀xA. ∀yA. x <=_r x +_f y) ∧
  (∀xA. ∀yA. y <=_r x +_f y) ∧
  (∀xA. ∀yA. ∀zA. x <=_r zy <=_r z --> x +_f y <=_r z)

lemma orderI:

  semilat (A, r, f) ==> order r

lemma closedI:

  semilat (A, r, f) ==> closed A f

lemma closedD:

  [| closed A f; xA; yA |] ==> x +_f yA

lemma closed_UNIV:

  closed UNIV f

lemma closed_f:

  [| semilat (A, r, f); xA; yA |] ==> x +_f yA

lemma refl_r:

  semilat (A, r, f) ==> x <=_r x

lemma antisym_r:

  [| semilat (A, r, f); x <=_r y; y <=_r x |] ==> x = y

lemma trans_r:

  [| semilat (A, r, f); x <=_r y; y <=_r z |] ==> x <=_r z

lemma ub1:

  [| semilat (A, r, f); xA; yA |] ==> x <=_r x +_f y

lemma ub2:

  [| semilat (A, r, f); xA; yA |] ==> y <=_r x +_f y

lemma lub:

  [| semilat (A, r, f); x <=_r z; y <=_r z; xA; yA; zA |]
  ==> x +_f y <=_r z

lemma plus_le_conv:

  [| semilat (A, r, f); xA; yA; zA |]
  ==> (x +_f y <=_r z) = (x <=_r zy <=_r z)

lemma le_iff_plus_unchanged:

  [| semilat (A, r, f); xA; yA |] ==> (x <=_r y) = (x +_f y = y)

lemma le_iff_plus_unchanged2:

  [| semilat (A, r, f); xA; yA |] ==> (x <=_r y) = (y +_f x = y)

lemma plus_assoc:

  [| semilat (A, r, f); aA; bA; cA |] ==> a +_f (b +_f c) = a +_f b +_f c

lemma plus_com_lemma:

  [| semilat (A, r, f); aA; bA |] ==> a +_f b <=_r b +_f a

lemma plus_commutative:

  [| semilat (A, r, f); aA; bA |] ==> a +_f b = b +_f a

lemma is_lubD:

  is_lub r x y u ==> is_ub r x y u ∧ (∀z. is_ub r x y z --> (u, z) ∈ r)

lemma is_ubI:

  [| (x, u) ∈ r; (y, u) ∈ r |] ==> is_ub r x y u

lemma is_ubD:

  is_ub r x y u ==> (x, u) ∈ r ∧ (y, u) ∈ r

lemma is_lub_bigger1:

  is_lub (r*) x y y = ((x, y) ∈ r*)

lemma is_lub_bigger2:

  is_lub (r*) x y x = ((y, x) ∈ r*)

lemma extend_lub:

  [| single_valued r; is_lub (r*) x y u; (x', x) ∈ r |] ==> ∃v. is_lub (r*) x' y v

lemma single_valued_has_lubs:

  [| single_valued r; (x, u) ∈ r*; (y, u) ∈ r* |] ==> Ex (is_lub (r*) x y)

lemma some_lub_conv:

  [| acyclic r; is_lub (r*) x y u |] ==> some_lub (r*) x y = u

lemma is_lub_some_lub:

  [| single_valued r; acyclic r; (x, u) ∈ r*; (y, u) ∈ r* |]
  ==> is_lub (r*) x y (some_lub (r*) x y)

An executable lub-finder

lemma acyclic_single_valued_finite:

  [| acyclic r; single_valued r; (x, y) ∈ r* |]
  ==> finite (r ∩ {a. (x, a) ∈ r*} × {b. (b, y) ∈ r*})

lemma exec_lub_conv:

  [| acyclic r; ∀x y. (x, y) ∈ r --> f x = y; is_lub (r*) x y u |]
  ==> exec_lub r f x y = u

lemma is_lub_exec_lub:

  [| single_valued r; acyclic r; (x, u) ∈ r*; (y, u) ∈ r*;
     ∀x y. (x, y) ∈ r --> f x = y |]
  ==> is_lub (r*) x y (exec_lub r f x y)