author  paulson 
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parent 24825  c4f13ab78f9d 
child 26342  0f65fa163304 
permissions  rwrr 
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(* Title: CCL/Type.thy 
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ID: $Id$ 
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Author: Martin Coen 

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Copyright 1993 University of Cambridge 

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*) 

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header {* Types in CCL are defined as sets of terms *} 
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theory Type 

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imports Term 

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begin 

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consts 

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Subtype :: "['a set, 'a => o] => 'a set" 

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Bool :: "i set" 

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Unit :: "i set" 

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Plus :: "[i set, i set] => i set" (infixr "+" 55) 
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Pi :: "[i set, i => i set] => i set" 
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Sigma :: "[i set, i => i set] => i set" 

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Nat :: "i set" 

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List :: "i set => i set" 

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Lists :: "i set => i set" 

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ILists :: "i set => i set" 

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TAll :: "(i set => i set) => i set" (binder "TALL " 55) 
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TEx :: "(i set => i set) => i set" (binder "TEX " 55) 
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Lift :: "i set => i set" ("(3[_])") 
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SPLIT :: "[i, [i, i] => i set] => i set" 

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syntax 
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"@Pi" :: "[idt, i set, i set] => i set" ("(3PROD _:_./ _)" 
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[0,0,60] 60) 
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"@Sigma" :: "[idt, i set, i set] => i set" ("(3SUM _:_./ _)" 
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[0,0,60] 60) 
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"@>" :: "[i set, i set] => i set" ("(_ >/ _)" [54, 53] 53) 
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"@*" :: "[i set, i set] => i set" ("(_ */ _)" [56, 55] 55) 
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"@Subtype" :: "[idt, 'a set, o] => 'a set" ("(1{_: _ ./ _})") 
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translations 

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"PROD x:A. B" => "Pi(A, %x. B)" 

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"A > B" => "Pi(A, %_. B)" 
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"SUM x:A. B" => "Sigma(A, %x. B)" 
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"A * B" => "Sigma(A, %_. B)" 
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"{x: A. B}" == "Subtype(A, %x. B)" 
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print_translation {* 
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[("Pi", dependent_tr' ("@Pi", "@>")), 

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("Sigma", dependent_tr' ("@Sigma", "@*"))] *} 

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axioms 
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Subtype_def: "{x:A. P(x)} == {x. x:A & P(x)}" 

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Unit_def: "Unit == {x. x=one}" 

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Bool_def: "Bool == {x. x=true  x=false}" 

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Plus_def: "A+B == {x. (EX a:A. x=inl(a))  (EX b:B. x=inr(b))}" 

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Pi_def: "Pi(A,B) == {x. EX b. x=lam x. b(x) & (ALL x:A. b(x):B(x))}" 

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Sigma_def: "Sigma(A,B) == {x. EX a:A. EX b:B(a).x=<a,b>}" 

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Nat_def: "Nat == lfp(% X. Unit + X)" 

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List_def: "List(A) == lfp(% X. Unit + A*X)" 

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Lists_def: "Lists(A) == gfp(% X. Unit + A*X)" 
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ILists_def: "ILists(A) == gfp(% X.{} + A*X)" 

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Tall_def: "TALL X. B(X) == Inter({X. EX Y. X=B(Y)})" 
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Tex_def: "TEX X. B(X) == Union({X. EX Y. X=B(Y)})" 

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Lift_def: "[A] == A Un {bot}" 

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SPLIT_def: "SPLIT(p,B) == Union({A. EX x y. p=<x,y> & A=B(x,y)})" 
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lemmas simp_type_defs = 

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Subtype_def Unit_def Bool_def Plus_def Sigma_def Pi_def Lift_def Tall_def Tex_def 

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and ind_type_defs = Nat_def List_def 

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and simp_data_defs = one_def inl_def inr_def 

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and ind_data_defs = zero_def succ_def nil_def cons_def 

78 

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lemma subsetXH: "A <= B <> (ALL x. x:A > x:B)" 

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by blast 

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subsection {* Exhaustion Rules *} 

84 

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lemma EmptyXH: "!!a. a : {} <> False" 

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and SubtypeXH: "!!a A P. a : {x:A. P(x)} <> (a:A & P(a))" 

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and UnitXH: "!!a. a : Unit <> a=one" 

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and BoolXH: "!!a. a : Bool <> a=true  a=false" 

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and PlusXH: "!!a A B. a : A+B <> (EX x:A. a=inl(x))  (EX x:B. a=inr(x))" 

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and PiXH: "!!a A B. a : PROD x:A. B(x) <> (EX b. a=lam x. b(x) & (ALL x:A. b(x):B(x)))" 

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and SgXH: "!!a A B. a : SUM x:A. B(x) <> (EX x:A. EX y:B(x).a=<x,y>)" 

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unfolding simp_type_defs by blast+ 

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lemmas XHs = EmptyXH SubtypeXH UnitXH BoolXH PlusXH PiXH SgXH 

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lemma LiftXH: "a : [A] <> (a=bot  a:A)" 

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and TallXH: "a : TALL X. B(X) <> (ALL X. a:B(X))" 

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and TexXH: "a : TEX X. B(X) <> (EX X. a:B(X))" 

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unfolding simp_type_defs by blast+ 

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ML {* 

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bind_thms ("case_rls", XH_to_Es (thms "XHs")); 

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*} 

104 

105 

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subsection {* Canonical Type Rules *} 

107 

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lemma oneT: "one : Unit" 

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and trueT: "true : Bool" 

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and falseT: "false : Bool" 

111 
and lamT: "!!b B. [ !!x. x:A ==> b(x):B(x) ] ==> lam x. b(x) : Pi(A,B)" 

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and pairT: "!!b B. [ a:A; b:B(a) ] ==> <a,b>:Sigma(A,B)" 

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and inlT: "a:A ==> inl(a) : A+B" 

114 
and inrT: "b:B ==> inr(b) : A+B" 

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by (blast intro: XHs [THEN iffD2])+ 

116 

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lemmas canTs = oneT trueT falseT pairT lamT inlT inrT 

118 

119 

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subsection {* NonCanonical Type Rules *} 

121 

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lemma lem: "[ a:B(u); u=v ] ==> a : B(v)" 

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by blast 

124 

125 

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ML {* 

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local 

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val lemma = thm "lem" 

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val bspec = thm "bspec" 

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val bexE = thm "bexE" 

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in 

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fun mk_ncanT_tac ctxt defs top_crls crls s = prove_goalw (ProofContext.theory_of ctxt) defs s 
20140  134 
(fn major::prems => [(resolve_tac ([major] RL top_crls) 1), 
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(REPEAT_SOME (eresolve_tac (crls @ [exE,bexE,conjE,disjE]))), 

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(ALLGOALS (asm_simp_tac (local_simpset_of ctxt))), 
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(ALLGOALS (ares_tac (prems RL [lemma]) ORELSE' 
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etac bspec )), 

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(safe_tac (local_claset_of ctxt addSIs prems))]) 
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val ncanT_tac = mk_ncanT_tac @{context} [] case_rls case_rls 
20140  142 
end 
143 
*} 

144 

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ML {* 

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bind_thm ("ifT", ncanT_tac 

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"[ b:Bool; b=true ==> t:A(true); b=false ==> u:A(false) ] ==> if b then t else u : A(b)"); 

149 

150 
bind_thm ("applyT", ncanT_tac "[ f : Pi(A,B); a:A ] ==> f ` a : B(a)"); 

151 

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bind_thm ("splitT", ncanT_tac 

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"[ p:Sigma(A,B); !!x y. [ x:A; y:B(x); p=<x,y> ] ==> c(x,y):C(<x,y>) ] ==> split(p,c):C(p)"); 

154 

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bind_thm ("whenT", ncanT_tac 

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"[ p:A+B; !!x.[ x:A; p=inl(x) ] ==> a(x):C(inl(x)); !!y.[ y:B; p=inr(y) ] ==> b(y):C(inr(y)) ] ==> when(p,a,b) : C(p)"); 

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*} 

158 

159 
lemmas ncanTs = ifT applyT splitT whenT 

160 

161 

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subsection {* Subtypes *} 

163 

164 
lemma SubtypeD1: "a : Subtype(A, P) ==> a : A" 

165 
and SubtypeD2: "a : Subtype(A, P) ==> P(a)" 

166 
by (simp_all add: SubtypeXH) 

167 

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lemma SubtypeI: "[ a:A; P(a) ] ==> a : {x:A. P(x)}" 

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by (simp add: SubtypeXH) 

170 

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lemma SubtypeE: "[ a : {x:A. P(x)}; [ a:A; P(a) ] ==> Q ] ==> Q" 

172 
by (simp add: SubtypeXH) 

173 

174 

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subsection {* Monotonicity *} 

176 

177 
lemma idM: "mono (%X. X)" 

178 
apply (rule monoI) 

179 
apply assumption 

180 
done 

181 

182 
lemma constM: "mono(%X. A)" 

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apply (rule monoI) 

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apply (rule subset_refl) 

185 
done 

186 

187 
lemma "mono(%X. A(X)) ==> mono(%X.[A(X)])" 

188 
apply (rule subsetI [THEN monoI]) 

189 
apply (drule LiftXH [THEN iffD1]) 

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apply (erule disjE) 

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apply (erule disjI1 [THEN LiftXH [THEN iffD2]]) 

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apply (rule disjI2 [THEN LiftXH [THEN iffD2]]) 

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apply (drule (1) monoD) 

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apply blast 

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done 

196 

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lemma SgM: 

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"[ mono(%X. A(X)); !!x X. x:A(X) ==> mono(%X. B(X,x)) ] ==> 

199 
mono(%X. Sigma(A(X),B(X)))" 

200 
by (blast intro!: subsetI [THEN monoI] canTs elim!: case_rls 

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dest!: monoD [THEN subsetD]) 

202 

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lemma PiM: 

204 
"[ !!x. x:A ==> mono(%X. B(X,x)) ] ==> mono(%X. Pi(A,B(X)))" 

205 
by (blast intro!: subsetI [THEN monoI] canTs elim!: case_rls 

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dest!: monoD [THEN subsetD]) 

207 

208 
lemma PlusM: 

209 
"[ mono(%X. A(X)); mono(%X. B(X)) ] ==> mono(%X. A(X)+B(X))" 

210 
by (blast intro!: subsetI [THEN monoI] canTs elim!: case_rls 

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dest!: monoD [THEN subsetD]) 

212 

213 

214 
subsection {* Recursive types *} 

215 

216 
subsubsection {* Conversion Rules for Fixed Points via monotonicity and Tarski *} 

217 

218 
lemma NatM: "mono(%X. Unit+X)"; 

219 
apply (rule PlusM constM idM)+ 

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done 

221 

222 
lemma def_NatB: "Nat = Unit + Nat" 

223 
apply (rule def_lfp_Tarski [OF Nat_def]) 

224 
apply (rule NatM) 

225 
done 

226 

227 
lemma ListM: "mono(%X.(Unit+Sigma(A,%y. X)))" 

228 
apply (rule PlusM SgM constM idM)+ 

229 
done 

230 

231 
lemma def_ListB: "List(A) = Unit + A * List(A)" 

232 
apply (rule def_lfp_Tarski [OF List_def]) 

233 
apply (rule ListM) 

234 
done 

235 

236 
lemma def_ListsB: "Lists(A) = Unit + A * Lists(A)" 

237 
apply (rule def_gfp_Tarski [OF Lists_def]) 

238 
apply (rule ListM) 

239 
done 

240 

241 
lemma IListsM: "mono(%X.({} + Sigma(A,%y. X)))" 

242 
apply (rule PlusM SgM constM idM)+ 

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done 

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245 
lemma def_IListsB: "ILists(A) = {} + A * ILists(A)" 

246 
apply (rule def_gfp_Tarski [OF ILists_def]) 

247 
apply (rule IListsM) 

248 
done 

249 

250 
lemmas ind_type_eqs = def_NatB def_ListB def_ListsB def_IListsB 

251 

252 

253 
subsection {* Exhaustion Rules *} 

254 

255 
lemma NatXH: "a : Nat <> (a=zero  (EX x:Nat. a=succ(x)))" 

256 
and ListXH: "a : List(A) <> (a=[]  (EX x:A. EX xs:List(A).a=x$xs))" 

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and ListsXH: "a : Lists(A) <> (a=[]  (EX x:A. EX xs:Lists(A).a=x$xs))" 

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and IListsXH: "a : ILists(A) <> (EX x:A. EX xs:ILists(A).a=x$xs)" 

259 
unfolding ind_data_defs 

260 
by (rule ind_type_eqs [THEN XHlemma1], blast intro!: canTs elim!: case_rls)+ 

261 

262 
lemmas iXHs = NatXH ListXH 

263 

264 
ML {* bind_thms ("icase_rls", XH_to_Es (thms "iXHs")) *} 

265 

266 

267 
subsection {* Type Rules *} 

268 

269 
lemma zeroT: "zero : Nat" 

270 
and succT: "n:Nat ==> succ(n) : Nat" 

271 
and nilT: "[] : List(A)" 

272 
and consT: "[ h:A; t:List(A) ] ==> h$t : List(A)" 

273 
by (blast intro: iXHs [THEN iffD2])+ 

274 

275 
lemmas icanTs = zeroT succT nilT consT 

276 

277 
ML {* 

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val incanT_tac = mk_ncanT_tac @{context} [] (thms "icase_rls") (thms "case_rls"); 
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280 
bind_thm ("ncaseT", incanT_tac 

281 
"[ n:Nat; n=zero ==> b:C(zero); !!x.[ x:Nat; n=succ(x) ] ==> c(x):C(succ(x)) ] ==> ncase(n,b,c) : C(n)"); 

282 

283 
bind_thm ("lcaseT", incanT_tac 

284 
"[ l:List(A); l=[] ==> b:C([]); !!h t.[ h:A; t:List(A); l=h$t ] ==> c(h,t):C(h$t) ] ==> lcase(l,b,c) : C(l)"); 

285 
*} 

286 

287 
lemmas incanTs = ncaseT lcaseT 

288 

289 

290 
subsection {* Induction Rules *} 

291 

292 
lemmas ind_Ms = NatM ListM 

293 

294 
lemma Nat_ind: "[ n:Nat; P(zero); !!x.[ x:Nat; P(x) ] ==> P(succ(x)) ] ==> P(n)" 

295 
apply (unfold ind_data_defs) 

296 
apply (erule def_induct [OF Nat_def _ NatM]) 

297 
apply (blast intro: canTs elim!: case_rls) 

298 
done 

299 

300 
lemma List_ind: 

301 
"[ l:List(A); P([]); !!x xs.[ x:A; xs:List(A); P(xs) ] ==> P(x$xs) ] ==> P(l)" 

302 
apply (unfold ind_data_defs) 

303 
apply (erule def_induct [OF List_def _ ListM]) 

304 
apply (blast intro: canTs elim!: case_rls) 

305 
done 

306 

307 
lemmas inds = Nat_ind List_ind 

308 

309 

310 
subsection {* Primitive Recursive Rules *} 

311 

312 
lemma nrecT: 

313 
"[ n:Nat; b:C(zero); 

314 
!!x g.[ x:Nat; g:C(x) ] ==> c(x,g):C(succ(x)) ] ==> 

315 
nrec(n,b,c) : C(n)" 

316 
by (erule Nat_ind) auto 

317 

318 
lemma lrecT: 

319 
"[ l:List(A); b:C([]); 

320 
!!x xs g.[ x:A; xs:List(A); g:C(xs) ] ==> c(x,xs,g):C(x$xs) ] ==> 

321 
lrec(l,b,c) : C(l)" 

322 
by (erule List_ind) auto 

323 

324 
lemmas precTs = nrecT lrecT 

325 

326 

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subsection {* Theorem proving *} 

328 

329 
lemma SgE2: 

330 
"[ <a,b> : Sigma(A,B); [ a:A; b:B(a) ] ==> P ] ==> P" 

331 
unfolding SgXH by blast 

332 

333 
(* General theorem proving ignores noncanonical termformers, *) 

334 
(*  intro rules are type rules for canonical terms *) 

335 
(*  elim rules are case rules (no noncanonical terms appear) *) 

336 

337 
ML {* bind_thms ("XHEs", XH_to_Es (thms "XHs")) *} 

338 

339 
lemmas [intro!] = SubtypeI canTs icanTs 

340 
and [elim!] = SubtypeE XHEs 

341 

342 

343 
subsection {* Infinite Data Types *} 

344 

345 
lemma lfp_subset_gfp: "mono(f) ==> lfp(f) <= gfp(f)" 

346 
apply (rule lfp_lowerbound [THEN subset_trans]) 

347 
apply (erule gfp_lemma3) 

348 
apply (rule subset_refl) 

349 
done 

350 

351 
lemma gfpI: 

352 
assumes "a:A" 

353 
and "!!x X.[ x:A; ALL y:A. t(y):X ] ==> t(x) : B(X)" 

354 
shows "t(a) : gfp(B)" 

355 
apply (rule coinduct) 

356 
apply (rule_tac P = "%x. EX y:A. x=t (y)" in CollectI) 

357 
apply (blast intro!: prems)+ 

358 
done 

359 

360 
lemma def_gfpI: 

361 
"[ C==gfp(B); a:A; !!x X.[ x:A; ALL y:A. t(y):X ] ==> t(x) : B(X) ] ==> 

362 
t(a) : C" 

363 
apply unfold 

364 
apply (erule gfpI) 

365 
apply blast 

366 
done 

367 

368 
(* EG *) 

369 
lemma "letrec g x be zero$g(x) in g(bot) : Lists(Nat)" 

370 
apply (rule refl [THEN UnitXH [THEN iffD2], THEN Lists_def [THEN def_gfpI]]) 

371 
apply (subst letrecB) 

372 
apply (unfold cons_def) 

373 
apply blast 

374 
done 

375 

376 

377 
subsection {* Lemmas and tactics for using the rule @{text 

378 
"coinduct3"} on @{text "[="} and @{text "="} *} 

379 

380 
lemma lfpI: "[ mono(f); a : f(lfp(f)) ] ==> a : lfp(f)" 

381 
apply (erule lfp_Tarski [THEN ssubst]) 

382 
apply assumption 

383 
done 

384 

385 
lemma ssubst_single: "[ a=a'; a' : A ] ==> a : A" 

386 
by simp 

387 

388 
lemma ssubst_pair: "[ a=a'; b=b'; <a',b'> : A ] ==> <a,b> : A" 

389 
by simp 

390 

391 

392 
(***) 

393 

394 
ML {* 

395 

396 
local 

397 
val lfpI = thm "lfpI" 

398 
val coinduct3_mono_lemma = thm "coinduct3_mono_lemma" 

399 
fun mk_thm s = prove_goal (the_context ()) s (fn mono::prems => 

400 
[fast_tac (claset () addIs ((mono RS coinduct3_mono_lemma RS lfpI)::prems)) 1]) 

401 
in 

402 
val ci3_RI = mk_thm "[ mono(Agen); a : R ] ==> a : lfp(%x. Agen(x) Un R Un A)" 

403 
val ci3_AgenI = mk_thm "[ mono(Agen); a : Agen(lfp(%x. Agen(x) Un R Un A)) ] ==> a : lfp(%x. Agen(x) Un R Un A)" 

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val ci3_AI = mk_thm "[ mono(Agen); a : A ] ==> a : lfp(%x. Agen(x) Un R Un A)" 

405 

406 
fun mk_genIs thy defs genXH gen_mono s = prove_goalw thy defs s 

407 
(fn prems => [rtac (genXH RS iffD2) 1, 

408 
simp_tac (simpset ()) 1, 

409 
TRY (fast_tac (claset () addIs 

410 
([genXH RS iffD2,gen_mono RS coinduct3_mono_lemma RS lfpI] 

411 
@ prems)) 1)]) 

412 
end; 

413 

414 
bind_thm ("ci3_RI", ci3_RI); 

415 
bind_thm ("ci3_AgenI", ci3_AgenI); 

416 
bind_thm ("ci3_AI", ci3_AI); 

417 
*} 

418 

419 

420 
subsection {* POgen *} 

421 

422 
lemma PO_refl: "<a,a> : PO" 

423 
apply (rule po_refl [THEN PO_iff [THEN iffD1]]) 

424 
done 

425 

426 
ML {* 

427 

428 
val POgenIs = map (mk_genIs (the_context ()) (thms "data_defs") (thm "POgenXH") (thm "POgen_mono")) 

429 
["<true,true> : POgen(R)", 

430 
"<false,false> : POgen(R)", 

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"[ <a,a'> : R; <b,b'> : R ] ==> <<a,b>,<a',b'>> : POgen(R)", 

432 
"[!!x. <b(x),b'(x)> : R ] ==><lam x. b(x),lam x. b'(x)> : POgen(R)", 

433 
"<one,one> : POgen(R)", 

434 
"<a,a'> : lfp(%x. POgen(x) Un R Un PO) ==> <inl(a),inl(a')> : POgen(lfp(%x. POgen(x) Un R Un PO))", 

435 
"<b,b'> : lfp(%x. POgen(x) Un R Un PO) ==> <inr(b),inr(b')> : POgen(lfp(%x. POgen(x) Un R Un PO))", 

436 
"<zero,zero> : POgen(lfp(%x. POgen(x) Un R Un PO))", 

437 
"<n,n'> : lfp(%x. POgen(x) Un R Un PO) ==> <succ(n),succ(n')> : POgen(lfp(%x. POgen(x) Un R Un PO))", 

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"<[],[]> : POgen(lfp(%x. POgen(x) Un R Un PO))", 

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"[ <h,h'> : lfp(%x. POgen(x) Un R Un PO); <t,t'> : lfp(%x. POgen(x) Un R Un PO) ] ==> <h$t,h'$t'> : POgen(lfp(%x. POgen(x) Un R Un PO))"]; 

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fun POgen_tac (rla,rlb) i = 

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SELECT_GOAL (CLASET safe_tac) i THEN 

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rtac (rlb RS (rla RS (thm "ssubst_pair"))) i THEN 

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(REPEAT (resolve_tac (POgenIs @ [thm "PO_refl" RS (thm "POgen_mono" RS ci3_AI)] @ 

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(POgenIs RL [thm "POgen_mono" RS ci3_AgenI]) @ [thm "POgen_mono" RS ci3_RI]) i)); 

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*} 

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subsection {* EQgen *} 

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lemma EQ_refl: "<a,a> : EQ" 

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apply (rule refl [THEN EQ_iff [THEN iffD1]]) 

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done 

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ML {* 

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val EQgenIs = map (mk_genIs (the_context ()) (thms "data_defs") (thm "EQgenXH") (thm "EQgen_mono")) 

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["<true,true> : EQgen(R)", 

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"<false,false> : EQgen(R)", 

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"[ <a,a'> : R; <b,b'> : R ] ==> <<a,b>,<a',b'>> : EQgen(R)", 

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"[!!x. <b(x),b'(x)> : R ] ==> <lam x. b(x),lam x. b'(x)> : EQgen(R)", 

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"<one,one> : EQgen(R)", 

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"<a,a'> : lfp(%x. EQgen(x) Un R Un EQ) ==> <inl(a),inl(a')> : EQgen(lfp(%x. EQgen(x) Un R Un EQ))", 

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"<b,b'> : lfp(%x. EQgen(x) Un R Un EQ) ==> <inr(b),inr(b')> : EQgen(lfp(%x. EQgen(x) Un R Un EQ))", 

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"<zero,zero> : EQgen(lfp(%x. EQgen(x) Un R Un EQ))", 

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"<n,n'> : lfp(%x. EQgen(x) Un R Un EQ) ==> <succ(n),succ(n')> : EQgen(lfp(%x. EQgen(x) Un R Un EQ))", 

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"<[],[]> : EQgen(lfp(%x. EQgen(x) Un R Un EQ))", 

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"[ <h,h'> : lfp(%x. EQgen(x) Un R Un EQ); <t,t'> : lfp(%x. EQgen(x) Un R Un EQ) ] ==> <h$t,h'$t'> : EQgen(lfp(%x. EQgen(x) Un R Un EQ))"]; 

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fun EQgen_raw_tac i = 

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(REPEAT (resolve_tac (EQgenIs @ [@{thm EQ_refl} RS (@{thm EQgen_mono} RS ci3_AI)] @ 
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(EQgenIs RL [@{thm EQgen_mono} RS ci3_AgenI]) @ [@{thm EQgen_mono} RS ci3_RI]) i)) 
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(* Goals of the form R <= EQgen(R)  rewrite elements <a,b> : EQgen(R) using rews and *) 

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(* then reduce this to a goal <a',b'> : R (hopefully?) *) 

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(* rews are rewrite rules that would cause looping in the simpifier *) 

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fun EQgen_tac ctxt rews i = 
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SELECT_GOAL 
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(TRY (safe_tac (local_claset_of ctxt)) THEN 
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resolve_tac ((rews@[refl]) RL ((rews@[refl]) RL [@{thm ssubst_pair}])) i THEN 
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ALLGOALS (simp_tac (local_simpset_of ctxt)) THEN 
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ALLGOALS EQgen_raw_tac) i 
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*} 

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end 