(* Title: Residuals.thy ID: $Id: Residuals.thy,v 1.12 2005/06/17 14:15:11 haftmann Exp $ Author: Ole Rasmussen Copyright 1995 University of Cambridge Logic Image: ZF *) theory Residuals imports Substitution begin consts Sres :: "i" residuals :: "[i,i,i]=>i" "|>" :: "[i,i]=>i" (infixl 70) translations "residuals(u,v,w)" == " \ Sres" inductive domains "Sres" <= "redexes*redexes*redexes" intros Res_Var: "n \ nat ==> residuals(Var(n),Var(n),Var(n))" Res_Fun: "[|residuals(u,v,w)|]==> residuals(Fun(u),Fun(v),Fun(w))" Res_App: "[|residuals(u1,v1,w1); residuals(u2,v2,w2); b \ bool|]==> residuals(App(b,u1,u2),App(0,v1,v2),App(b,w1,w2))" Res_redex: "[|residuals(u1,v1,w1); residuals(u2,v2,w2); b \ bool|]==> residuals(App(b,Fun(u1),u2),App(1,Fun(v1),v2),w2/w1)" type_intros subst_type nat_typechecks redexes.intros bool_typechecks defs res_func_def: "u |> v == THE w. residuals(u,v,w)" subsection{*Setting up rule lists*} declare Sres.intros [intro] declare Sreg.intros [intro] declare subst_type [intro] inductive_cases [elim!]: "residuals(Var(n),Var(n),v)" "residuals(Fun(t),Fun(u),v)" "residuals(App(b, u1, u2), App(0, v1, v2),v)" "residuals(App(b, u1, u2), App(1, Fun(v1), v2),v)" "residuals(Var(n),u,v)" "residuals(Fun(t),u,v)" "residuals(App(b, u1, u2), w,v)" "residuals(u,Var(n),v)" "residuals(u,Fun(t),v)" "residuals(w,App(b, u1, u2),v)" inductive_cases [elim!]: "Var(n) <== u" "Fun(n) <== u" "u <== Fun(n)" "App(1,Fun(t),a) <== u" "App(0,t,a) <== u" inductive_cases [elim!]: "Fun(t) \ redexes" declare Sres.intros [simp] subsection{*residuals is a partial function*} lemma residuals_function [rule_format]: "residuals(u,v,w) ==> \w1. residuals(u,v,w1) --> w1 = w" by (erule Sres.induct, force+) lemma residuals_intro [rule_format]: "u~v ==> regular(v) --> (\w. residuals(u,v,w))" by (erule Scomp.induct, force+) lemma comp_resfuncD: "[| u~v; regular(v) |] ==> residuals(u, v, THE w. residuals(u, v, w))" apply (frule residuals_intro, assumption, clarify) apply (subst the_equality) apply (blast intro: residuals_function)+ done subsection{*Residual function*} lemma res_Var [simp]: "n \ nat ==> Var(n) |> Var(n) = Var(n)" by (unfold res_func_def, blast) lemma res_Fun [simp]: "[|s~t; regular(t)|]==> Fun(s) |> Fun(t) = Fun(s |> t)" apply (unfold res_func_def) apply (blast intro: comp_resfuncD residuals_function) done lemma res_App [simp]: "[|s~u; regular(u); t~v; regular(v); b \ bool|] ==> App(b,s,t) |> App(0,u,v) = App(b, s |> u, t |> v)" apply (unfold res_func_def) apply (blast dest!: comp_resfuncD intro: residuals_function) done lemma res_redex [simp]: "[|s~u; regular(u); t~v; regular(v); b \ bool|] ==> App(b,Fun(s),t) |> App(1,Fun(u),v) = (t |> v)/ (s |> u)" apply (unfold res_func_def) apply (blast elim!: redexes.free_elims dest!: comp_resfuncD intro: residuals_function) done lemma resfunc_type [simp]: "[|s~t; regular(t)|]==> regular(t) --> s |> t \ redexes" by (erule Scomp.induct, auto) subsection{*Commutation theorem*} lemma sub_comp [simp]: "u<==v ==> u~v" by (erule Ssub.induct, simp_all) lemma sub_preserve_reg [rule_format, simp]: "u<==v ==> regular(v) --> regular(u)" by (erule Ssub.induct, auto) lemma residuals_lift_rec: "[|u~v; k \ nat|]==> regular(v)--> (\n \ nat. lift_rec(u,n) |> lift_rec(v,n) = lift_rec(u |> v,n))" apply (erule Scomp.induct, safe) apply (simp_all add: lift_rec_Var subst_Var lift_subst) done lemma residuals_subst_rec: "u1~u2 ==> \v1 v2. v1~v2 --> regular(v2) --> regular(u2) --> (\n \ nat. subst_rec(v1,u1,n) |> subst_rec(v2,u2,n) = subst_rec(v1 |> v2, u1 |> u2,n))" apply (erule Scomp.induct, safe) apply (simp_all add: lift_rec_Var subst_Var residuals_lift_rec) apply (drule_tac psi = "\x.?P (x) " in asm_rl) apply (simp add: substitution) done lemma commutation [simp]: "[|u1~u2; v1~v2; regular(u2); regular(v2)|] ==> (v1/u1) |> (v2/u2) = (v1 |> v2)/(u1 |> u2)" by (simp add: residuals_subst_rec) subsection{*Residuals are comp and regular*} lemma residuals_preserve_comp [rule_format, simp]: "u~v ==> \w. u~w --> v~w --> regular(w) --> (u|>w) ~ (v|>w)" by (erule Scomp.induct, force+) lemma residuals_preserve_reg [rule_format, simp]: "u~v ==> regular(u) --> regular(v) --> regular(u|>v)" apply (erule Scomp.induct, auto) done subsection{*Preservation lemma*} lemma union_preserve_comp: "u~v ==> v ~ (u un v)" by (erule Scomp.induct, simp_all) lemma preservation [rule_format]: "u ~ v ==> regular(v) --> u|>v = (u un v)|>v" apply (erule Scomp.induct, safe) apply (drule_tac [3] psi = "Fun (?u) |> ?v = ?w" in asm_rl) apply (auto simp add: union_preserve_comp comp_sym_iff) done declare sub_comp [THEN comp_sym, simp] subsection{*Prism theorem*} (* Having more assumptions than needed -- removed below *) lemma prism_l [rule_format]: "v<==u ==> regular(u) --> (\w. w~v --> w~u --> w |> u = (w|>v) |> (u|>v))" by (erule Ssub.induct, force+) lemma prism: "[|v <== u; regular(u); w~v|] ==> w |> u = (w|>v) |> (u|>v)" apply (rule prism_l) apply (rule_tac [4] comp_trans, auto) done subsection{*Levy's Cube Lemma*} lemma cube: "[|u~v; regular(v); regular(u); w~u|]==> (w|>u) |> (v|>u) = (w|>v) |> (u|>v)" apply (subst preservation [of u], assumption, assumption) apply (subst preservation [of v], erule comp_sym, assumption) apply (subst prism [symmetric, of v]) apply (simp add: union_r comp_sym_iff) apply (simp add: union_preserve_regular comp_sym_iff) apply (erule comp_trans, assumption) apply (simp add: prism [symmetric] union_l union_preserve_regular comp_sym_iff union_sym) done subsection{*paving theorem*} lemma paving: "[|w~u; w~v; regular(u); regular(v)|]==> \uv vu. (w|>u) |> vu = (w|>v) |> uv & (w|>u)~vu & regular(vu) & (w|>v)~uv & regular(uv) " apply (subgoal_tac "u~v") apply (safe intro!: exI) apply (rule cube) apply (simp_all add: comp_sym_iff) apply (blast intro: residuals_preserve_comp comp_trans comp_sym)+ done end