src/HOL/Tools/ComputeHOL.thy

--- a/src/HOL/Tools/ComputeHOL.thy	Tue Sep 29 22:15:54 2009 +0200
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,191 +0,0 @@
-theory ComputeHOL
-imports Complex_Main "~~/src/Tools/Compute_Oracle/Compute_Oracle"
-begin
-
-lemma Trueprop_eq_eq: "Trueprop X == (X == True)" by (simp add: atomize_eq)
-lemma meta_eq_trivial: "x == y \<Longrightarrow> x == y" by simp
-lemma meta_eq_imp_eq: "x == y \<Longrightarrow> x = y" by auto
-lemma eq_trivial: "x = y \<Longrightarrow> x = y" by auto
-lemma bool_to_true: "x :: bool \<Longrightarrow> x == True"  by simp
-lemma transmeta_1: "x = y \<Longrightarrow> y == z \<Longrightarrow> x = z" by simp
-lemma transmeta_2: "x == y \<Longrightarrow> y = z \<Longrightarrow> x = z" by simp
-lemma transmeta_3: "x == y \<Longrightarrow> y == z \<Longrightarrow> x = z" by simp
-
-
-(**** compute_if ****)
-
-lemma If_True: "If True = (\<lambda> x y. x)" by ((rule ext)+,auto)
-lemma If_False: "If False = (\<lambda> x y. y)" by ((rule ext)+, auto)
-
-lemmas compute_if = If_True If_False
-
-(**** compute_bool ****)
-
-lemma bool1: "(\<not> True) = False"  by blast
-lemma bool2: "(\<not> False) = True"  by blast
-lemma bool3: "(P \<and> True) = P" by blast
-lemma bool4: "(True \<and> P) = P" by blast
-lemma bool5: "(P \<and> False) = False" by blast
-lemma bool6: "(False \<and> P) = False" by blast
-lemma bool7: "(P \<or> True) = True" by blast
-lemma bool8: "(True \<or> P) = True" by blast
-lemma bool9: "(P \<or> False) = P" by blast
-lemma bool10: "(False \<or> P) = P" by blast
-lemma bool11: "(True \<longrightarrow> P) = P" by blast
-lemma bool12: "(P \<longrightarrow> True) = True" by blast
-lemma bool13: "(True \<longrightarrow> P) = P" by blast
-lemma bool14: "(P \<longrightarrow> False) = (\<not> P)" by blast
-lemma bool15: "(False \<longrightarrow> P) = True" by blast
-lemma bool16: "(False = False) = True" by blast
-lemma bool17: "(True = True) = True" by blast
-lemma bool18: "(False = True) = False" by blast
-lemma bool19: "(True = False) = False" by blast
-
-lemmas compute_bool = bool1 bool2 bool3 bool4 bool5 bool6 bool7 bool8 bool9 bool10 bool11 bool12 bool13 bool14 bool15 bool16 bool17 bool18 bool19
-
-
-(*** compute_pair ***)
-
-lemma compute_fst: "fst (x,y) = x" by simp
-lemma compute_snd: "snd (x,y) = y" by simp
-lemma compute_pair_eq: "((a, b) = (c, d)) = (a = c \<and> b = d)" by auto
-
-lemma prod_case_simp: "prod_case f (x,y) = f x y" by simp
-
-lemmas compute_pair = compute_fst compute_snd compute_pair_eq prod_case_simp
-
-(*** compute_option ***)
-
-lemma compute_the: "the (Some x) = x" by simp
-lemma compute_None_Some_eq: "(None = Some x) = False" by auto
-lemma compute_Some_None_eq: "(Some x = None) = False" by auto
-lemma compute_None_None_eq: "(None = None) = True" by auto
-lemma compute_Some_Some_eq: "(Some x = Some y) = (x = y)" by auto
-
-definition
-   option_case_compute :: "'b option \<Rightarrow> 'a \<Rightarrow> ('b \<Rightarrow> 'a) \<Rightarrow> 'a"
-where
-   "option_case_compute opt a f = option_case a f opt"
-
-lemma option_case_compute: "option_case = (\<lambda> a f opt. option_case_compute opt a f)"
-  by (simp add: option_case_compute_def)
-
-lemma option_case_compute_None: "option_case_compute None = (\<lambda> a f. a)"
-  apply (rule ext)+
-  apply (simp add: option_case_compute_def)
-  done
-
-lemma option_case_compute_Some: "option_case_compute (Some x) = (\<lambda> a f. f x)"
-  apply (rule ext)+
-  apply (simp add: option_case_compute_def)
-  done
-
-lemmas compute_option_case = option_case_compute option_case_compute_None option_case_compute_Some
-
-lemmas compute_option = compute_the compute_None_Some_eq compute_Some_None_eq compute_None_None_eq compute_Some_Some_eq compute_option_case
-
-(**** compute_list_length ****)
-
-lemma length_cons:"length (x#xs) = 1 + (length xs)"
-  by simp
-
-lemma length_nil: "length [] = 0"
-  by simp
-
-lemmas compute_list_length = length_nil length_cons
-
-(*** compute_list_case ***)
-
-definition
-  list_case_compute :: "'b list \<Rightarrow> 'a \<Rightarrow> ('b \<Rightarrow> 'b list \<Rightarrow> 'a) \<Rightarrow> 'a"
-where
-  "list_case_compute l a f = list_case a f l"
-
-lemma list_case_compute: "list_case = (\<lambda> (a::'a) f (l::'b list). list_case_compute l a f)"
-  apply (rule ext)+
-  apply (simp add: list_case_compute_def)
-  done
-
-lemma list_case_compute_empty: "list_case_compute ([]::'b list) = (\<lambda> (a::'a) f. a)"
-  apply (rule ext)+
-  apply (simp add: list_case_compute_def)
-  done
-
-lemma list_case_compute_cons: "list_case_compute (u#v) = (\<lambda> (a::'a) f. (f (u::'b) v))"
-  apply (rule ext)+
-  apply (simp add: list_case_compute_def)
-  done
-
-lemmas compute_list_case = list_case_compute list_case_compute_empty list_case_compute_cons
-
-(*** compute_list_nth ***)
-(* Of course, you will need computation with nats for this to work \<dots> *)
-
-lemma compute_list_nth: "((x#xs) ! n) = (if n = 0 then x else (xs ! (n - 1)))"
-  by (cases n, auto)
-  
-(*** compute_list ***)
-
-lemmas compute_list = compute_list_case compute_list_length compute_list_nth
-
-(*** compute_let ***)
-
-lemmas compute_let = Let_def
-
-(***********************)
-(* Everything together *)
-(***********************)
-
-lemmas compute_hol = compute_if compute_bool compute_pair compute_option compute_list compute_let
-
-ML {*
-signature ComputeHOL =
-sig
-  val prep_thms : thm list -> thm list
-  val to_meta_eq : thm -> thm
-  val to_hol_eq : thm -> thm
-  val symmetric : thm -> thm 
-  val trans : thm -> thm -> thm
-end
-
-structure ComputeHOL : ComputeHOL =
-struct
-
-local
-fun lhs_of eq = fst (Thm.dest_equals (cprop_of eq));
-in
-fun rewrite_conv [] ct = raise CTERM ("rewrite_conv", [])
-  | rewrite_conv (eq :: eqs) ct =
-      Thm.instantiate (Thm.match (lhs_of eq, ct)) eq
-      handle Pattern.MATCH => rewrite_conv eqs ct;
-end
-
-val convert_conditions = Conv.fconv_rule (Conv.prems_conv ~1 (Conv.try_conv (rewrite_conv [@{thm "Trueprop_eq_eq"}])))
-
-val eq_th = @{thm "HOL.eq_reflection"}
-val meta_eq_trivial = @{thm "ComputeHOL.meta_eq_trivial"}
-val bool_to_true = @{thm "ComputeHOL.bool_to_true"}
-
-fun to_meta_eq th = eq_th OF [th] handle THM _ => meta_eq_trivial OF [th] handle THM _ => bool_to_true OF [th]
-
-fun to_hol_eq th = @{thm "meta_eq_imp_eq"} OF [th] handle THM _ => @{thm "eq_trivial"} OF [th] 
-
-fun prep_thms ths = map (convert_conditions o to_meta_eq) ths
-
-fun symmetric th = @{thm "HOL.sym"} OF [th] handle THM _ => @{thm "Pure.symmetric"} OF [th]
-
-local
-    val trans_HOL = @{thm "HOL.trans"}
-    val trans_HOL_1 = @{thm "ComputeHOL.transmeta_1"}
-    val trans_HOL_2 = @{thm "ComputeHOL.transmeta_2"}
-    val trans_HOL_3 = @{thm "ComputeHOL.transmeta_3"}
-    fun tr [] th1 th2 = trans_HOL OF [th1, th2]
-      | tr (t::ts) th1 th2 = (t OF [th1, th2] handle THM _ => tr ts th1 th2) 
-in
-  fun trans th1 th2 = tr [trans_HOL, trans_HOL_1, trans_HOL_2, trans_HOL_3] th1 th2
-end
-
-end
-*}
-
-end