language-Modula2-0.1: examples/Modula-2_Libraries/C.-Lins_Modula-2_Software_Component_Library/Vol3/TREES/BBSUMIU.MOD
(*
7.4 Weight-Balanced Binary Search Tree Utilities
*)
IMPLEMENTATION MODULE BBSUMIU;
(*====================================================================
Version : V2.01 08 December 1989.
Compiler : JPI TopSpeed Modula-2
Code size: OBJ file has 1531 bytes.
Component: BB Tree SUMI Utilities - Print Tree Tool
INTRODUCTION
This module provides the facility for printing a binary tree.
REVISION HISTORY
v1.00 17 Mar 1988 C. Lins
Initial implementation for TML Modula-2.
v1.01 29 Jan 1989 C. Lins
Changed to use Key and Data aliases for generic items.
v2.00 08 Oct 1989 C. Lins
Created generic pc version
v2.01 08 Dec 1989 I.S.C. Houston.
Adapted to JPI Compiler:
Used type transfer functions instead of VAL.
Used shortened library module names for DOS and OS/2.
(C) Copyright 1989 Charles A. Lins
=====================================================================*)
FROM TreeTypes IMPORT
(*--Type*) Key, Data;
FROM BBSUMI IMPORT
(*--Type*) Tree, NodePtr, Weight,
(*--Proc*) RootOf, LeftOf, RightOf, IsNull, KeyOf, DataOf,
WeightOf, IsEmpty;
(*-----------------------*)
(*
7.4.1 Utility Selectors
HeightOf returns the height of the given tree. Height may be computed by
subtracting the level of the ≡lowest≡ node in the tree from the level of
the root. Complexity O(log2 n).
*)
PROCEDURE HeightOf ( theTree : Tree (*-- in *))
: CARDINAL (*-- out *);
VAR maxLevel : CARDINAL; (*-- level of the lowest node so far *)
PROCEDURE CountLevels ( theNode : NodePtr (*-- in *);
theLevel: CARDINAL (*-- in *));
BEGIN
IF ~IsNull(theNode) THEN
IF (theLevel > maxLevel) THEN
maxLevel := theLevel;
END (*--if*);
CountLevels(LeftOf(theNode), theLevel+1);
CountLevels(RightOf(theNode), theLevel+1);
END (*--if*);
END CountLevels;
BEGIN
maxLevel := 1;
IF ~IsEmpty(theTree) THEN
CountLevels(RootOf(theTree), 1);
END (*--if*);
RETURN maxLevel - 1;
END HeightOf;
(*-------------------------*)
(*
7.4.2 Debugging Iterators
PrintTree iterates over the given tree such that the nodes may be
printed. Trees are normally displayed with the root at the top and
the leaves at the bottom. To simplify the printing process, PrintTree
displays the tree rotated 90Æ to the left. Thus the root is shown at
the left of the page/screen with the leaves at the right. Furthermore,
the left branches are shown towards the bottom of the display and the
right branches at the top. A constant indentation of two spaces between
levels is used.
The algorithm used here is a variation on the inorder tree traversal. So
that the tree is displayed properly rotated, the processing of the left
and right branches are reversed. This algorithm is derived from that
given by Wirth in [8].
*)
PROCEDURE PrintTree ( theTree: Tree (*--in *);
print : PrintProc (*--in *));
PROCEDURE DoPrintTree ( theSubtree : NodePtr (*--in *);
theLevel : CARDINAL (*--in *));
BEGIN
IF ~IsNull(theSubtree) THEN
DoPrintTree(RightOf(theSubtree), theLevel+1);
print(theLevel, KeyOf(theSubtree), DataOf(theSubtree),
WeightOf(theSubtree));
DoPrintTree(LeftOf(theSubtree), theLevel+1);
END (*--if*);
END DoPrintTree;
BEGIN
IF ~IsEmpty(theTree) THEN
DoPrintTree(RootOf(theTree), 0);
END (*--if*);
END PrintTree;
(*-------------------------*)
END BBSUMIU.