(* Title: HOL/ex/BT.thy
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1995 University of Cambridge
Binary trees
*)
header {* Binary trees *}
theory BT imports Main begin
datatype 'a bt =
Lf
| Br 'a "'a bt" "'a bt"
primrec n_nodes :: "'a bt => nat" where
"n_nodes Lf = 0"
| "n_nodes (Br a t1 t2) = Suc (n_nodes t1 + n_nodes t2)"
primrec n_leaves :: "'a bt => nat" where
"n_leaves Lf = Suc 0"
| "n_leaves (Br a t1 t2) = n_leaves t1 + n_leaves t2"
primrec depth :: "'a bt => nat" where
"depth Lf = 0"
| "depth (Br a t1 t2) = Suc (max (depth t1) (depth t2))"
primrec reflect :: "'a bt => 'a bt" where
"reflect Lf = Lf"
| "reflect (Br a t1 t2) = Br a (reflect t2) (reflect t1)"
primrec bt_map :: "('a => 'b) => ('a bt => 'b bt)" where
"bt_map f Lf = Lf"
| "bt_map f (Br a t1 t2) = Br (f a) (bt_map f t1) (bt_map f t2)"
primrec preorder :: "'a bt => 'a list" where
"preorder Lf = []"
| "preorder (Br a t1 t2) = [a] @ (preorder t1) @ (preorder t2)"
primrec inorder :: "'a bt => 'a list" where
"inorder Lf = []"
| "inorder (Br a t1 t2) = (inorder t1) @ [a] @ (inorder t2)"
primrec postorder :: "'a bt => 'a list" where
"postorder Lf = []"
| "postorder (Br a t1 t2) = (postorder t1) @ (postorder t2) @ [a]"
primrec append :: "'a bt => 'a bt => 'a bt" where
"append Lf t = t"
| "append (Br a t1 t2) t = Br a (append t1 t) (append t2 t)"
text {* \medskip BT simplification *}
lemma n_leaves_reflect: "n_leaves (reflect t) = n_leaves t"
apply (induct t)
apply auto
done
lemma n_nodes_reflect: "n_nodes (reflect t) = n_nodes t"
apply (induct t)
apply auto
done
lemma depth_reflect: "depth (reflect t) = depth t"
apply (induct t)
apply auto
done
text {*
The famous relationship between the numbers of leaves and nodes.
*}
lemma n_leaves_nodes: "n_leaves t = Suc (n_nodes t)"
apply (induct t)
apply auto
done
lemma reflect_reflect_ident: "reflect (reflect t) = t"
apply (induct t)
apply auto
done
lemma bt_map_reflect: "bt_map f (reflect t) = reflect (bt_map f t)"
apply (induct t)
apply simp_all
done
lemma preorder_bt_map: "preorder (bt_map f t) = map f (preorder t)"
apply (induct t)
apply simp_all
done
lemma inorder_bt_map: "inorder (bt_map f t) = map f (inorder t)"
apply (induct t)
apply simp_all
done
lemma postorder_bt_map: "postorder (bt_map f t) = map f (postorder t)"
apply (induct t)
apply simp_all
done
lemma depth_bt_map [simp]: "depth (bt_map f t) = depth t"
apply (induct t)
apply simp_all
done
lemma n_leaves_bt_map [simp]: "n_leaves (bt_map f t) = n_leaves t"
apply (induct t)
apply (simp_all add: left_distrib)
done
lemma preorder_reflect: "preorder (reflect t) = rev (postorder t)"
apply (induct t)
apply simp_all
done
lemma inorder_reflect: "inorder (reflect t) = rev (inorder t)"
apply (induct t)
apply simp_all
done
lemma postorder_reflect: "postorder (reflect t) = rev (preorder t)"
apply (induct t)
apply simp_all
done
text {*
Analogues of the standard properties of the append function for lists.
*}
lemma append_assoc [simp]:
"append (append t1 t2) t3 = append t1 (append t2 t3)"
apply (induct t1)
apply simp_all
done
lemma append_Lf2 [simp]: "append t Lf = t"
apply (induct t)
apply simp_all
done
lemma depth_append [simp]: "depth (append t1 t2) = depth t1 + depth t2"
apply (induct t1)
apply (simp_all add: max_add_distrib_left)
done
lemma n_leaves_append [simp]:
"n_leaves (append t1 t2) = n_leaves t1 * n_leaves t2"
apply (induct t1)
apply (simp_all add: left_distrib)
done
lemma bt_map_append:
"bt_map f (append t1 t2) = append (bt_map f t1) (bt_map f t2)"
apply (induct t1)
apply simp_all
done
end