--- a/src/HOLCF/Streams.thy Tue Sep 07 15:59:16 2004 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,564 +0,0 @@
-(* Title: HOLCF/Streams.thy
- ID: $Id$
- Author: Borislav Gajanovic and David von Oheimb
-
-Stream domains with concatenation.
-TODO: HOLCF/ex/Stream.* should be integrated into this file.
-*)
-
-theory Streams = Stream :
-
-(* ----------------------------------------------------------------------- *)
-
-lemma stream_neq_UU: "x~=UU ==> EX a as. x=a&&as & a~=UU"
-by (simp add: stream_exhaust_eq,auto)
-
-lemma stream_prefix1: "[| x<<y; xs<<ys |] ==> x&&xs << y&&ys"
-by (insert stream_prefix' [of y "x&&xs" ys],force)
-
-lemma stream_take_le_mono : "k<=n ==> stream_take k$s1 << stream_take n$s1"
-apply (insert chain_stream_take [of s1])
-by (drule chain_mono3,auto)
-
-lemma mono_stream_take: "s1 << s2 ==> stream_take n$s1 << stream_take n$s2"
-by (simp add: monofun_cfun_arg)
-
-lemma stream_take_prefix [simp]: "stream_take n$s << s"
-apply (subgoal_tac "s=(LUB n. stream_take n$s)")
- apply (erule ssubst, rule is_ub_thelub)
- apply (simp only: chain_stream_take)
-by (simp only: stream_reach2)
-
-lemma stream_take_take_less:"stream_take k$(stream_take n$s) << stream_take k$s"
-by (rule monofun_cfun_arg,auto)
-
-(* ----------------------------------------------------------------------- *)
-
-lemma slen_rt_mono: "#s2 <= #s1 ==> #(rt$s2) <= #(rt$s1)"
-apply (rule stream.casedist [of s1])
- apply (rule stream.casedist [of s2],simp+)
-by (rule stream.casedist [of s2],auto)
-
-lemma slen_take_lemma4 [rule_format]:
- "!s. stream_take n$s ~= s --> #(stream_take n$s) = Fin n"
-apply (induct_tac n,auto simp add: Fin_0)
-apply (case_tac "s=UU",simp)
-by (drule stream_neq_UU,auto)
-
-lemma slen_take_lemma5: "#(stream_take n$s) <= Fin n";
-apply (case_tac "stream_take n$s = s")
- apply (simp add: slen_take_eq_rev)
-by (simp add: slen_take_lemma4)
-
-lemma stream_take_idempotent [simp]:
- "stream_take n$(stream_take n$s) = stream_take n$s"
-apply (case_tac "stream_take n$s = s")
-apply (auto,insert slen_take_lemma4 [of n s]);
-by (auto,insert slen_take_lemma1 [of "stream_take n$s" n],simp)
-
-lemma stream_take_take_Suc [simp]: "stream_take n$(stream_take (Suc n)$s) =
- stream_take n$s"
-apply (simp add: po_eq_conv,auto)
- apply (simp add: stream_take_take_less)
-apply (subgoal_tac "stream_take n$s = stream_take n$(stream_take n$s)")
- apply (erule ssubst)
- apply (rule_tac monofun_cfun_arg)
- apply (insert chain_stream_take [of s])
-by (simp add: chain_def,simp)
-
-lemma mono_stream_take_pred:
- "stream_take (Suc n)$s1 << stream_take (Suc n)$s2 ==>
- stream_take n$s1 << stream_take n$s2"
-by (drule mono_stream_take [of _ _ n],simp)
-
-lemma stream_take_lemma10 [rule_format]:
- "ALL k<=n. stream_take n$s1 << stream_take n$s2
- --> stream_take k$s1 << stream_take k$s2"
-apply (induct_tac n,simp,clarsimp)
-apply (case_tac "k=Suc n",blast)
-apply (erule_tac x="k" in allE)
-by (drule mono_stream_take_pred,simp)
-
-lemma stream_take_finite [simp]: "stream_finite (stream_take n$s)"
-apply (simp add: stream.finite_def)
-by (rule_tac x="n" in exI,simp)
-
-lemma slen_stream_take_finite [simp]: "#(stream_take n$s) ~= \<infinity>"
-by (simp add: slen_def)
-
-lemma stream_take_Suc_neq: "stream_take (Suc n)$s ~=s ==>
- stream_take n$s ~= stream_take (Suc n)$s"
-apply auto
-apply (subgoal_tac "stream_take n$s ~=s")
- apply (insert slen_take_lemma4 [of n s],auto)
-apply (rule stream.casedist [of s],simp)
-apply (simp add: inat_defs split:inat_splits)
-by (simp add: slen_take_lemma4)
-
-
-(* ----------------------------------------------------------------------- *)
-
-consts
-
- i_rt :: "nat => 'a stream => 'a stream" (* chops the first i elements *)
- i_th :: "nat => 'a stream => 'a" (* the i-th element *)
-
- sconc :: "'a stream => 'a stream => 'a stream" (infixr "ooo" 65)
- constr_sconc :: "'a stream => 'a stream => 'a stream" (* constructive *)
- constr_sconc' :: "nat => 'a stream => 'a stream => 'a stream"
-
-defs
- i_rt_def: "i_rt == %i s. iterate i rt s"
- i_th_def: "i_th == %i s. ft$(i_rt i s)"
-
- sconc_def: "s1 ooo s2 == case #s1 of
- Fin n => (SOME s. (stream_take n$s=s1) & (i_rt n s = s2))
- | \<infinity> => s1"
-
- constr_sconc_def: "constr_sconc s1 s2 == case #s1 of
- Fin n => constr_sconc' n s1 s2
- | \<infinity> => s1"
-primrec
- constr_sconc'_0: "constr_sconc' 0 s1 s2 = s2"
- constr_sconc'_Suc: "constr_sconc' (Suc n) s1 s2 = ft$s1 &&
- constr_sconc' n (rt$s1) s2"
-
-
-(* ----------------------------------------------------------------------- *)
- section "i_rt"
-(* ----------------------------------------------------------------------- *)
-
-lemma i_rt_UU [simp]: "i_rt n UU = UU"
-apply (simp add: i_rt_def)
-by (rule iterate.induct,auto)
-
-lemma i_rt_0 [simp]: "i_rt 0 s = s"
-by (simp add: i_rt_def)
-
-lemma i_rt_Suc [simp]: "a ~= UU ==> i_rt (Suc n) (a&&s) = i_rt n s"
-by (simp add: i_rt_def iterate_Suc2 del: iterate_Suc)
-
-lemma i_rt_Suc_forw: "i_rt (Suc n) s = i_rt n (rt$s)"
-by (simp only: i_rt_def iterate_Suc2)
-
-lemma i_rt_Suc_back:"i_rt (Suc n) s = rt$(i_rt n s)"
-by (simp only: i_rt_def,auto)
-
-lemma i_rt_mono: "x << s ==> i_rt n x << i_rt n s"
-by (simp add: i_rt_def monofun_rt_mult)
-
-lemma i_rt_ij_lemma: "Fin (i + j) <= #x ==> Fin j <= #(i_rt i x)"
-by (simp add: i_rt_def slen_rt_mult)
-
-lemma slen_i_rt_mono: "#s2 <= #s1 ==> #(i_rt n s2) <= #(i_rt n s1)"
-apply (induct_tac n,auto)
-apply (simp add: i_rt_Suc_back)
-by (drule slen_rt_mono,simp)
-
-lemma i_rt_take_lemma1 [rule_format]: "ALL s. i_rt n (stream_take n$s) = UU"
-apply (induct_tac n);
- apply (simp add: i_rt_Suc_back,auto)
-apply (case_tac "s=UU",auto)
-by (drule stream_neq_UU,simp add: i_rt_Suc_forw,auto)
-
-lemma i_rt_slen: "(i_rt n s = UU) = (stream_take n$s = s)"
-apply auto
- apply (insert i_rt_ij_lemma [of n "Suc 0" s]);
- apply (subgoal_tac "#(i_rt n s)=0")
- apply (case_tac "stream_take n$s = s",simp+)
- apply (insert slen_take_eq [of n s],simp)
- apply (simp add: inat_defs split:inat_splits)
- apply (simp add: slen_take_eq )
-by (simp, insert i_rt_take_lemma1 [of n s],simp)
-
-lemma i_rt_lemma_slen: "#s=Fin n ==> i_rt n s = UU"
-by (simp add: i_rt_slen slen_take_lemma1)
-
-lemma stream_finite_i_rt [simp]: "stream_finite (i_rt n s) = stream_finite s"
-apply (induct_tac n, auto)
- apply (rule stream.casedist [of "s"], auto simp del: i_rt_Suc)
-by (simp add: i_rt_Suc_back stream_finite_rt_eq)+
-
-lemma take_i_rt_len_lemma: "ALL sl x j t. Fin sl = #x & n <= sl &
- #(stream_take n$x) = Fin t & #(i_rt n x)= Fin j
- --> Fin (j + t) = #x"
-apply (induct_tac n,auto)
- apply (simp add: inat_defs)
-apply (case_tac "x=UU",auto)
- apply (simp add: inat_defs)
-apply (drule stream_neq_UU,auto)
-apply (subgoal_tac "EX k. Fin k = #as",clarify)
- apply (erule_tac x="k" in allE)
- apply (erule_tac x="as" in allE,auto)
- apply (erule_tac x="THE p. Suc p = t" in allE,auto)
- apply (simp add: inat_defs split:inat_splits)
- apply (simp add: inat_defs split:inat_splits)
- apply (simp only: the_equality)
- apply (simp add: inat_defs split:inat_splits)
- apply force
-by (simp add: inat_defs split:inat_splits)
-
-lemma take_i_rt_len:
-"[| Fin sl = #x; n <= sl; #(stream_take n$x) = Fin t; #(i_rt n x) = Fin j |] ==>
- Fin (j + t) = #x"
-by (blast intro: take_i_rt_len_lemma [rule_format])
-
-
-(* ----------------------------------------------------------------------- *)
- section "i_th"
-(* ----------------------------------------------------------------------- *)
-
-lemma i_th_i_rt_step:
-"[| i_th n s1 << i_th n s2; i_rt (Suc n) s1 << i_rt (Suc n) s2 |] ==>
- i_rt n s1 << i_rt n s2"
-apply (simp add: i_th_def i_rt_Suc_back)
-apply (rule stream.casedist [of "i_rt n s1"],simp)
-apply (rule stream.casedist [of "i_rt n s2"],auto)
-by (drule stream_prefix1,auto)
-
-lemma i_th_stream_take_Suc [rule_format]:
- "ALL s. i_th n (stream_take (Suc n)$s) = i_th n s"
-apply (induct_tac n,auto)
- apply (simp add: i_th_def)
- apply (case_tac "s=UU",auto)
- apply (drule stream_neq_UU,auto)
-apply (case_tac "s=UU",simp add: i_th_def)
-apply (drule stream_neq_UU,auto)
-by (simp add: i_th_def i_rt_Suc_forw)
-
-lemma last_lemma10: "stream_take (Suc n)$s1 << stream_take (Suc n)$s2 ==>
- i_th n s1 << i_th n s2"
-apply (rule i_th_stream_take_Suc [THEN subst])
-apply (rule i_th_stream_take_Suc [THEN subst]) back
-apply (simp add: i_th_def)
-apply (rule monofun_cfun_arg)
-by (erule i_rt_mono)
-
-lemma i_th_last: "i_th n s && UU = i_rt n (stream_take (Suc n)$s)"
-apply (insert surjectiv_scons [of "i_rt n (stream_take (Suc n)$s)"])
-apply (rule i_th_stream_take_Suc [THEN subst])
-apply (simp add: i_th_def i_rt_Suc_back [symmetric])
-by (simp add: i_rt_take_lemma1)
-
-lemma i_th_last_eq:
-"i_th n s1 = i_th n s2 ==> i_rt n (stream_take (Suc n)$s1) = i_rt n (stream_take (Suc n)$s2)"
-apply (insert i_th_last [of n s1])
-apply (insert i_th_last [of n s2])
-by auto
-
-lemma i_th_prefix_lemma:
-"[| k <= n; stream_take (Suc n)$s1 << stream_take (Suc n)$s2 |] ==>
- i_th k s1 << i_th k s2"
-apply (subgoal_tac "stream_take (Suc k)$s1 << stream_take (Suc k)$s2")
- apply (simp add: last_lemma10)
-by (blast intro: stream_take_lemma10)
-
-lemma take_i_rt_prefix_lemma1:
- "stream_take (Suc n)$s1 << stream_take (Suc n)$s2 ==>
- i_rt (Suc n) s1 << i_rt (Suc n) s2 ==>
- i_rt n s1 << i_rt n s2 & stream_take n$s1 << stream_take n$s2"
-apply auto
- apply (insert i_th_prefix_lemma [of n n s1 s2])
- apply (rule i_th_i_rt_step,auto)
-by (drule mono_stream_take_pred,simp)
-
-lemma take_i_rt_prefix_lemma:
-"[| stream_take n$s1 << stream_take n$s2; i_rt n s1 << i_rt n s2 |] ==> s1 << s2"
-apply (case_tac "n=0",simp)
-apply (insert neq0_conv [of n])
-apply (insert not0_implies_Suc [of n],auto)
-apply (subgoal_tac "stream_take 0$s1 << stream_take 0$s2 &
- i_rt 0 s1 << i_rt 0 s2")
- defer 1
- apply (rule zero_induct,blast)
- apply (blast dest: take_i_rt_prefix_lemma1)
-by simp
-
-lemma streams_prefix_lemma: "(s1 << s2) =
- (stream_take n$s1 << stream_take n$s2 & i_rt n s1 << i_rt n s2)";
-apply auto
- apply (simp add: monofun_cfun_arg)
- apply (simp add: i_rt_mono)
-by (erule take_i_rt_prefix_lemma,simp)
-
-lemma streams_prefix_lemma1:
- "[| stream_take n$s1 = stream_take n$s2; i_rt n s1 = i_rt n s2 |] ==> s1 = s2"
-apply (simp add: po_eq_conv,auto)
- apply (insert streams_prefix_lemma)
- by blast+
-
-
-(* ----------------------------------------------------------------------- *)
- section "sconc"
-(* ----------------------------------------------------------------------- *)
-
-lemma UU_sconc [simp]: " UU ooo s = s "
-by (simp add: sconc_def inat_defs)
-
-lemma scons_neq_UU: "a~=UU ==> a && s ~=UU"
-by auto
-
-lemma singleton_sconc [rule_format, simp]: "x~=UU --> (x && UU) ooo y = x && y"
-apply (simp add: sconc_def inat_defs split:inat_splits,auto)
-apply (rule someI2_ex,auto)
- apply (rule_tac x="x && y" in exI,auto)
-apply (simp add: i_rt_Suc_forw)
-apply (case_tac "xa=UU",simp)
-by (drule stream_neq_UU,auto)
-
-lemma ex_sconc [rule_format]:
- "ALL k y. #x = Fin k --> (EX w. stream_take k$w = x & i_rt k w = y)"
-apply (case_tac "#x")
- apply (rule stream_finite_ind [of x],auto)
- apply (simp add: stream.finite_def)
- apply (drule slen_take_lemma1,blast)
- apply (simp add: inat_defs split:inat_splits)+
-apply (erule_tac x="y" in allE,auto)
-by (rule_tac x="a && w" in exI,auto)
-
-lemma rt_sconc1: "Fin n = #x ==> i_rt n (x ooo y) = y";
-apply (simp add: sconc_def inat_defs split:inat_splits , arith?,auto)
-apply (rule someI2_ex,auto)
-by (drule ex_sconc,simp)
-
-lemma sconc_inj2: "\<lbrakk>Fin n = #x; x ooo y = x ooo z\<rbrakk> \<Longrightarrow> y = z"
-apply (frule_tac y=y in rt_sconc1)
-by (auto elim: rt_sconc1)
-
-lemma sconc_UU [simp]:"s ooo UU = s"
-apply (case_tac "#s")
- apply (simp add: sconc_def inat_defs)
- apply (rule someI2_ex)
- apply (rule_tac x="s" in exI)
- apply auto
- apply (drule slen_take_lemma1,auto)
- apply (simp add: i_rt_lemma_slen)
- apply (drule slen_take_lemma1,auto)
- apply (simp add: i_rt_slen)
-by (simp add: sconc_def inat_defs)
-
-lemma stream_take_sconc [simp]: "Fin n = #x ==> stream_take n$(x ooo y) = x"
-apply (simp add: sconc_def)
-apply (simp add: inat_defs split:inat_splits,auto)
-apply (rule someI2_ex,auto)
-by (drule ex_sconc,simp)
-
-lemma scons_sconc [rule_format,simp]: "a~=UU --> (a && x) ooo y = a && x ooo y"
-apply (case_tac "#x",auto)
- apply (simp add: sconc_def)
- apply (rule someI2_ex)
- apply (drule ex_sconc,simp)
- apply (rule someI2_ex,auto)
- apply (simp add: i_rt_Suc_forw)
- apply (rule_tac x="a && x" in exI,auto)
- apply (case_tac "xa=UU",auto)
- apply (drule_tac s="stream_take nat$x" in scons_neq_UU)
- apply (simp add: i_rt_Suc_forw)
- apply (drule stream_neq_UU,clarsimp)
- apply (drule streams_prefix_lemma1,simp+)
-by (simp add: sconc_def)
-
-lemma ft_sconc: "x ~= UU ==> ft$(x ooo y) = ft$x"
-by (rule stream.casedist [of x],auto)
-
-lemma sconc_assoc: "(x ooo y) ooo z = x ooo y ooo z"
-apply (case_tac "#x")
- apply (rule stream_finite_ind [of x],auto simp del: scons_sconc)
- apply (simp add: stream.finite_def del: scons_sconc)
- apply (drule slen_take_lemma1,auto simp del: scons_sconc)
- apply (case_tac "a = UU", auto)
-by (simp add: sconc_def)
-
-
-(* ----------------------------------------------------------------------- *)
-
-lemma sconc_mono: "y << y' ==> x ooo y << x ooo y'"
-apply (case_tac "#x")
- apply (rule stream_finite_ind [of "x"])
- apply (auto simp add: stream.finite_def)
- apply (drule slen_take_lemma1,blast)
- by (simp add: stream_prefix',auto simp add: sconc_def)
-
-lemma sconc_mono1 [simp]: "x << x ooo y"
-by (rule sconc_mono [of UU, simplified])
-
-(* ----------------------------------------------------------------------- *)
-
-lemma empty_sconc [simp]: "(x ooo y = UU) = (x = UU & y = UU)"
-apply (case_tac "#x",auto)
- by (insert sconc_mono1 [of x y],auto);
-
-(* ----------------------------------------------------------------------- *)
-
-lemma rt_sconc [rule_format, simp]: "s~=UU --> rt$(s ooo x) = rt$s ooo x"
-by (rule stream.casedist,auto)
-
-(* ----------------------------------------------------------------------- *)
-
-lemma sconc_lemma [rule_format, simp]: "ALL s. stream_take n$s ooo i_rt n s = s"
-apply (induct_tac n,auto)
-apply (case_tac "s=UU",auto)
-by (drule stream_neq_UU,auto)
-
-(* ----------------------------------------------------------------------- *)
- subsection "pointwise equality"
-(* ----------------------------------------------------------------------- *)
-
-lemma ex_last_stream_take_scons: "stream_take (Suc n)$s =
- stream_take n$s ooo i_rt n (stream_take (Suc n)$s)"
-by (insert sconc_lemma [of n "stream_take (Suc n)$s"],simp)
-
-lemma i_th_stream_take_eq:
-"!!n. ALL n. i_th n s1 = i_th n s2 ==> stream_take n$s1 = stream_take n$s2"
-apply (induct_tac n,auto)
-apply (subgoal_tac "stream_take (Suc na)$s1 =
- stream_take na$s1 ooo i_rt na (stream_take (Suc na)$s1)")
- apply (subgoal_tac "i_rt na (stream_take (Suc na)$s1) =
- i_rt na (stream_take (Suc na)$s2)")
- apply (subgoal_tac "stream_take (Suc na)$s2 =
- stream_take na$s2 ooo i_rt na (stream_take (Suc na)$s2)")
- apply (insert ex_last_stream_take_scons,simp)
- apply blast
- apply (erule_tac x="na" in allE)
- apply (insert i_th_last_eq [of _ s1 s2])
-by blast+
-
-lemma pointwise_eq_lemma[rule_format]: "ALL n. i_th n s1 = i_th n s2 ==> s1 = s2"
-by (insert i_th_stream_take_eq [THEN stream.take_lemmas],blast)
-
-(* ----------------------------------------------------------------------- *)
- subsection "finiteness"
-(* ----------------------------------------------------------------------- *)
-
-lemma slen_sconc_finite1:
- "[| #(x ooo y) = Infty; Fin n = #x |] ==> #y = Infty"
-apply (case_tac "#y ~= Infty",auto)
-apply (simp only: slen_infinite [symmetric])
-apply (drule_tac y=y in rt_sconc1)
-apply (insert stream_finite_i_rt [of n "x ooo y"])
-by (simp add: slen_infinite)
-
-lemma slen_sconc_infinite1: "#x=Infty ==> #(x ooo y) = Infty"
-by (simp add: sconc_def)
-
-lemma slen_sconc_infinite2: "#y=Infty ==> #(x ooo y) = Infty"
-apply (case_tac "#x")
- apply (simp add: sconc_def)
- apply (rule someI2_ex)
- apply (drule ex_sconc,auto)
- apply (erule contrapos_pp)
- apply (insert stream_finite_i_rt)
- apply (simp add: slen_infinite ,auto)
-by (simp add: sconc_def)
-
-lemma sconc_finite: "(#x~=Infty & #y~=Infty) = (#(x ooo y)~=Infty)"
-apply auto
- apply (case_tac "#x",auto)
- apply (erule contrapos_pp,simp)
- apply (erule slen_sconc_finite1,simp)
- apply (drule slen_sconc_infinite1 [of _ y],simp)
-by (drule slen_sconc_infinite2 [of _ x],simp)
-
-(* ----------------------------------------------------------------------- *)
-
-lemma slen_sconc_mono3: "[| Fin n = #x; Fin k = #(x ooo y) |] ==> n <= k"
-apply (insert slen_mono [of "x" "x ooo y"])
-by (simp add: inat_defs split: inat_splits)
-
-(* ----------------------------------------------------------------------- *)
- subsection "finite slen"
-(* ----------------------------------------------------------------------- *)
-
-lemma slen_sconc: "[| Fin n = #x; Fin m = #y |] ==> #(x ooo y) = Fin (n + m)"
-apply (case_tac "#(x ooo y)")
- apply (frule_tac y=y in rt_sconc1)
- apply (insert take_i_rt_len [of "THE j. Fin j = #(x ooo y)" "x ooo y" n n m],simp)
- apply (insert slen_sconc_mono3 [of n x _ y],simp)
-by (insert sconc_finite [of x y],auto)
-
-(* ----------------------------------------------------------------------- *)
- subsection "flat prefix"
-(* ----------------------------------------------------------------------- *)
-
-lemma sconc_prefix: "(s1::'a::flat stream) << s2 ==> EX t. s1 ooo t = s2"
-apply (case_tac "#s1")
- apply (subgoal_tac "stream_take nat$s1 = stream_take nat$s2");
- apply (rule_tac x="i_rt nat s2" in exI)
- apply (simp add: sconc_def)
- apply (rule someI2_ex)
- apply (drule ex_sconc)
- apply (simp,clarsimp,drule streams_prefix_lemma1)
- apply (simp+,rule slen_take_lemma3 [rule_format, of _ s1 s2]);
- apply (simp+,rule_tac x="UU" in exI)
-apply (insert slen_take_lemma3 [rule_format, of _ s1 s2]);
-by (rule stream.take_lemmas,simp)
-
-(* ----------------------------------------------------------------------- *)
- subsection "continuity"
-(* ----------------------------------------------------------------------- *)
-
-lemma chain_sconc: "chain S ==> chain (%i. (x ooo S i))"
-by (simp add: chain_def,auto simp add: sconc_mono)
-
-lemma chain_scons: "chain S ==> chain (%i. a && S i)"
-apply (simp add: chain_def,auto)
-by (rule monofun_cfun_arg,simp)
-
-lemma contlub_scons: "contlub (%x. a && x)"
-by (simp add: contlub_Rep_CFun2)
-
-lemma contlub_scons_lemma: "chain S ==> (LUB i. a && S i) = a && (LUB i. S i)"
-apply (insert contlub_scons [of a])
-by (simp only: contlub)
-
-lemma finite_lub_sconc: "chain Y ==> (stream_finite x) ==>
- (LUB i. x ooo Y i) = (x ooo (LUB i. Y i))"
-apply (rule stream_finite_ind [of x])
- apply (auto)
-apply (subgoal_tac "(LUB i. a && (s ooo Y i)) = a && (LUB i. s ooo Y i)")
- by (force,blast dest: contlub_scons_lemma chain_sconc)
-
-lemma contlub_sconc_lemma:
- "chain Y ==> (LUB i. x ooo Y i) = (x ooo (LUB i. Y i))"
-apply (case_tac "#x=Infty")
- apply (simp add: sconc_def)
- prefer 2
- apply (drule finite_lub_sconc,auto simp add: slen_infinite)
-apply (simp add: slen_def)
-apply (insert lub_const [of x] unique_lub [of _ x _])
-by (auto simp add: lub)
-
-lemma contlub_sconc: "contlub (%y. x ooo y)";
-by (rule contlubI, insert contlub_sconc_lemma [of _ x], simp);
-
-lemma monofun_sconc: "monofun (%y. x ooo y)"
-by (simp add: monofun sconc_mono)
-
-lemma cont_sconc: "cont (%y. x ooo y)"
-apply (rule monocontlub2cont)
- apply (rule monofunI, simp add: sconc_mono)
-by (rule contlub_sconc);
-
-
-(* ----------------------------------------------------------------------- *)
- section "constr_sconc"
-(* ----------------------------------------------------------------------- *)
-
-lemma constr_sconc_UUs [simp]: "constr_sconc UU s = s"
-by (simp add: constr_sconc_def inat_defs)
-
-lemma "x ooo y = constr_sconc x y"
-apply (case_tac "#x")
- apply (rule stream_finite_ind [of x],auto simp del: scons_sconc)
- defer 1
- apply (simp add: constr_sconc_def del: scons_sconc)
- apply (case_tac "#s")
- apply (simp add: inat_defs)
- apply (case_tac "a=UU",auto simp del: scons_sconc)
- apply (simp)
- apply (simp add: sconc_def)
- apply (simp add: constr_sconc_def)
-apply (simp add: stream.finite_def)
-by (drule slen_take_lemma1,auto)
-
-end