author | wenzelm |
Thu, 24 Nov 2005 00:00:20 +0100 | |
changeset 18242 | 2215049cd29c |
parent 16417 | 9bc16273c2d4 |
child 19736 | d8d0f8f51d69 |
permissions | -rw-r--r-- |
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(* Title: HOL/Induct/Tree.thy |
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ID: $Id$ |
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Author: Stefan Berghofer, TU Muenchen |
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Author: Lawrence C Paulson, Cambridge University Computer Laboratory |
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*) |
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header {* Infinitely branching trees *} |
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theory Tree imports Main begin |
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datatype 'a tree = |
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Atom 'a |
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| Branch "nat => 'a tree" |
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consts |
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map_tree :: "('a => 'b) => 'a tree => 'b tree" |
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primrec |
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"map_tree f (Atom a) = Atom (f a)" |
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"map_tree f (Branch ts) = Branch (\<lambda>x. map_tree f (ts x))" |
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lemma tree_map_compose: "map_tree g (map_tree f t) = map_tree (g \<circ> f) t" |
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by (induct t) simp_all |
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consts |
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exists_tree :: "('a => bool) => 'a tree => bool" |
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primrec |
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"exists_tree P (Atom a) = P a" |
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"exists_tree P (Branch ts) = (\<exists>x. exists_tree P (ts x))" |
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lemma exists_map: |
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"(!!x. P x ==> Q (f x)) ==> |
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exists_tree P ts ==> exists_tree Q (map_tree f ts)" |
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by (induct ts) auto |
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subsection{*The Brouwer ordinals, as in ZF/Induct/Brouwer.thy.*} |
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datatype brouwer = Zero | Succ "brouwer" | Lim "nat => brouwer" |
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text{*Addition of ordinals*} |
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consts |
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add :: "[brouwer,brouwer] => brouwer" |
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primrec |
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"add i Zero = i" |
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"add i (Succ j) = Succ (add i j)" |
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"add i (Lim f) = Lim (%n. add i (f n))" |
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lemma add_assoc: "add (add i j) k = add i (add j k)" |
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by (induct k) auto |
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text{*Multiplication of ordinals*} |
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consts |
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mult :: "[brouwer,brouwer] => brouwer" |
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primrec |
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"mult i Zero = Zero" |
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"mult i (Succ j) = add (mult i j) i" |
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"mult i (Lim f) = Lim (%n. mult i (f n))" |
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lemma add_mult_distrib: "mult i (add j k) = add (mult i j) (mult i k)" |
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by (induct k) (auto simp add: add_assoc) |
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lemma mult_assoc: "mult (mult i j) k = mult i (mult j k)" |
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by (induct k) (auto simp add: add_mult_distrib) |
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text{*We could probably instantiate some axiomatic type classes and use |
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the standard infix operators.*} |
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subsection{*A WF Ordering for The Brouwer ordinals (Michael Compton)*} |
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text{*To define recdef style functions we need an ordering on the Brouwer |
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ordinals. Start with a predecessor relation and form its transitive |
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closure. *} |
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constdefs |
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brouwer_pred :: "(brouwer * brouwer) set" |
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"brouwer_pred == \<Union>i. {(m,n). n = Succ m \<or> (EX f. n = Lim f & m = f i)}" |
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brouwer_order :: "(brouwer * brouwer) set" |
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"brouwer_order == brouwer_pred^+" |
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lemma wf_brouwer_pred: "wf brouwer_pred" |
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by(unfold wf_def brouwer_pred_def, clarify, induct_tac x, blast+) |
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lemma wf_brouwer_order: "wf brouwer_order" |
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by(unfold brouwer_order_def, rule wf_trancl[OF wf_brouwer_pred]) |
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lemma [simp]: "(j, Succ j) : brouwer_order" |
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by(auto simp add: brouwer_order_def brouwer_pred_def) |
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lemma [simp]: "(f n, Lim f) : brouwer_order" |
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by(auto simp add: brouwer_order_def brouwer_pred_def) |
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text{*Example of a recdef*} |
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consts |
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add2 :: "(brouwer*brouwer) => brouwer" |
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recdef add2 "inv_image brouwer_order (\<lambda> (x,y). y)" |
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"add2 (i, Zero) = i" |
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"add2 (i, (Succ j)) = Succ (add2 (i, j))" |
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"add2 (i, (Lim f)) = Lim (\<lambda> n. add2 (i, (f n)))" |
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(hints recdef_wf: wf_brouwer_order) |
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lemma add2_assoc: "add2 (add2 (i, j), k) = add2 (i, add2 (j, k))" |
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by (induct k) auto |
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end |