yap-6.3/library/trees.yap

/**
 * @file   trees.yap
 * @author  R.A.O'Keefe, This file has been included as an YAP library by Vitor Santos Costa, 1999
 *
 * @date   Wed Nov 18 01:30:42 2015
 * 
 * @brief   Updatable binary trees.
 * 
 * 
*/

:- module(trees, [
	get_label/3,
	list_to_tree/2,
	map_tree/3,
	put_label/4,
	tree_size/2,
	tree_to_list/2
    ]).


% 
%   File   : TREES.PL
%   Author :
%   Updated: 8 November 1983
%   Purpose: Updatable binary trees.


/** @defgroup trees Updatable Binary Trees
@{
@ingroup library

The following queue manipulation routines are available once
included with the `use_module(library(trees))` command.

These are the routines I meant to describe in DAI-WP-150, but the
    wrong version went in.  We have
+	list_to_tree : O(N)
+	tree_to_list : O(N)
+	tree_size    : O(N)
+	map_tree     : O(N)
+	get_label    : O(lg N)
+	put_label    : O(lg N)
    where N is the number of elements in the tree.  The way get_label
    and put_label work is worth noting: they build up a pattern which
    is matched against the whole tree when the position number finally
    reaches 1.  In effect they start out from the desired node and
    build up a path to the root.  They still cost O(lg N) time rather
    than O(N) because the patterns contain O(lg N) distinct variables,
    with no duplications.  put_label simultaneously builds up a pattern
    to match the old tree and a pattern to match the new tree.
*/

:- meta_predicate
        map_tree(2, ?, ?).

/*
:- mode
	get_label(+, +, ?),
	find_node(+, +, +),
	list_to_tree(+, -),
	list_to_tree(+, +, -),
	list_to_tree(+),
	map_tree(+, +, -),
	put_label(+, +, +, -),
	find_node(+, +, +, -, +),
	tree_size(+, ?),
	tree_size(+, +, -),
	tree_to_list(+, -),
	tree_to_list(+, -, -).
*/


/** @pred get_label(+ _Index_, + _Tree_, ? _Label_) 

Treats the tree as an array of  _N_ elements and returns the
 _Index_-th.

*/
get_label(N, Tree, Label) :-
	find_node(N, Tree, t(Label,_,_)).


	find_node(1, Tree, Tree) :- !.
	find_node(N, Tree, Node) :-
		N > 1,
		0 is N mod 2,
		M is N  /  2, !,
		find_node(M, Tree, t(_,Node,_)).
	find_node(N, Tree, Node) :-
		N > 2,
		1 is N mod 2,
		M is N  /  2, !,
		find_node(M, Tree, t(_,_,Node)).



/** @pred list_to_tree(+ _List_, - _Tree_) 


Takes a given  _List_ of  _N_ elements and constructs a binary
 _Tree_.

 
*/
list_to_tree(List, Tree) :-
	list_to_tree(List, [Tree|Tail], Tail).


	list_to_tree([Head|Tail], [t(Head,Left,Right)|Qhead], [Left,Right|Qtail]) :-
		list_to_tree(Tail, Qhead, Qtail).
	list_to_tree([], Qhead, []) :-
		list_to_tree(Qhead).
	

		list_to_tree([t|Qhead]) :-
			list_to_tree(Qhead).
		list_to_tree([]).



/** @pred map_tree(+ _Pred_, + _OldTree_, - _NewTree_) 


Holds when  _OldTree_ and  _NewTree_ are binary trees of the same shape
and `Pred(Old,New)` is true for corresponding elements of the two trees.

  is true when OldTree and NewTree are binary trees of the same shape
  and Pred(Old,New) is true for corresponding elements of the two trees.
  In fact this routine is perfectly happy constructing either tree given
  the other, I have given it the mode I have for that bogus reason
  "efficiency" and because it is normally used this way round.  This is
  really meant more as an illustration of how to map over trees than as
 a tool for everyday use.
*/
map_tree(Pred, t(Old,OLeft,ORight), t(New,NLeft,NRight)) :-
	once(call(Pred, Old, New)),
	map_tree(Pred, OLeft, NLeft),
	map_tree(Pred, ORight, NRight).
map_tree(_, t, t).

/** @pred put_label(+ _Index_, + _OldTree_, + _Label_, - _NewTree_) 


constructs a new tree the same shape as the old which moreover has the
same elements except that the  _Index_-th one is  _Label_.

  It constructs a new tree the same shape as the old which moreover has the
  same elements except that the Index-th one is Label.  Unlike the
  "arrays" of Arrays.Pl, OldTree is not modified and you can hang on to
  it as long as you please.  Note that O(lg N) new space is needed.
*/
put_label(N, Old, Label, New) :-
	find_node(N, Old, t(_,Left,Right), New, t(Label,Left,Right)).


	find_node(1, Old, Old, New, New) :- !.
	find_node(N, Old, OldSub, New, NewSub) :-
		N > 1,
		0 is N mod 2,
		M is N  /  2, !,
		find_node(M, Old, t(Label,OldSub,Right), New, t(Label,NewSub,Right)).
	find_node(N, Old, OldSub, New, NewSub) :-
		N > 2,
		1 is N mod 2,
		M is N  /  2, !,
		find_node(M, Old, t(Label,Left,OldSub), New, t(Label,Left,NewSub)).



/** @pred tree_size(+ _Tree_, - _Size_) 

  Calculates the number of elements in the  _Tree_.

  All trees made by  list_to_tree that are the same size have the same shape.
*/
tree_size(Tree, Size) :-
	tree_size(Tree, 0, Total), !,
	Size = Total.


	tree_size(t(_,Left,Right), SoFar, Total) :-
		tree_size(Right, SoFar, M),
		N is M+1, !,
		tree_size(Left, N, Total).
	tree_size(t, Accum, Accum).



/** @pred tree_to_list(+ _Tree_, - _List_) 


  Is the converse operation to list_to_tree..  Any mapping or checking
  operation can be done by converting the tree to a list, mapping or
  checking the list, and converting the result, if any, back to a tree.
  It is also easier for a human to read a list than a tree, as the
  order in the tree goes all over the place.
 */
tree_to_list(Tree, List) :-
	tree_to_list([Tree|Tail], Tail, List).


	tree_to_list([], [], []) :- !.
	tree_to_list([t|_], _, []) :- !.
	tree_to_list([t(Head,Left,Right)|Qhead], [Left,Right|Qtail], [Head|Tail]) :-
		tree_to_list(Qhead, Qtail, Tail).



list(0, []).
list(N, [N|L]) :- M is N-1, list(M, L).

%% @}