Printer-friendly versionThe representation of sequences in terms of lists generalizes
naturally to represent sequences whose elements may
themselves be sequences. For example, we can regard the object
((1 2) 3 4) constructed by
(cons (list 1 2) (list 3 4))
as a list of three items, the first of which is itself a list, (1 2). Indeed, this is suggested by the form in which the result is
printed by the interpreter. Figure 2.5 shows
the representation of this structure in terms of pairs.
Another way to think of sequences whose elements are sequences is as
trees. The elements of the sequence are the branches of the
tree, and elements that are themselves sequences are subtrees.
Figure 2.6 shows the structure in
figure 2.5 viewed as a tree.
Recursion is a natural tool for dealing with tree structures, since
we can often reduce operations on trees to operations on their
branches, which reduce in turn to operations on the branches of the
branches, and so on, until we reach the leaves of the tree.
As an example, compare the length procedure of
section 2.2.1 with the count-leaves procedure, which
returns the total number of leaves of a tree:
(define x (cons (list 1 2) (list 3 4)))
(length x)
3
(count-leaves x)
4
(list x x)
(((1 2) 3 4) ((1 2) 3 4))
(length (list x x))
2
(count-leaves (list x x))
8
To implement count-leaves, recall the recursive plan for computing length:
Length of a list x is 1 plus length of the cdr of x.Length of the empty list is 0.
Count-leaves is similar. The value for the empty list is the same:
Count-leaves of the empty list is 0.
But in the reduction step, where we strip off the car of the list, we must take into account that the car may itself be a tree whose leaves we need to count. Thus, the appropriate reduction step is
Count-leaves of a tree x is count-leaves of the car of x plus count-leaves of the cdr of x.
Finally, by taking cars we reach actual leaves, so we need another base case:
Count-leaves of a leaf is 1.
To aid in writing recursive procedures on trees, Scheme provides the primitive
predicate pair?, which tests whether its argument is a pair.
Here is the complete procedure:
(define (count-leaves x)
(cond ((null? x) 0)
((not (pair? x)) 1)
(else (+ (count-leaves (car x))
(count-leaves (cdr x))))))
Suppose we evaluate the expression (list 1 (list 2 (list 3 4))). Give the result printed by the interpreter, the corresponding
box-and-pointer structure, and the interpretation of this as a tree (as in figure 2.6).
Give combinations of cars and cdrs that will pick 7 from
each of the following lists:
(1 3 (5 7) 9)
((7))
(1 (2 (3 (4 (5 (6 7))))))
Suppose we define x and y to be two lists:
(define x (list 1 2 3))
(define y (list 4 5 6))
What result is printed by the interpreter in response to evaluating
each of the following expressions:
(append x y)
(cons x y)
(list x y)
Modify your reverse procedure of exercise 2.18 to
produce a deep-reverse procedure that takes a list as argument and returns as its value the list with its elements reversed and with
all sublists deep-reversed as well. For example,
(define x (list (list 1 2) (list 3 4)))
x
((1 2) (3 4))
(reverse x)
((3 4) (1 2))
(deep-reverse x)
((4 3) (2 1))
Write a procedure fringe that takes as argument a tree
(represented as a list) and returns a list whose elements are all the
leaves of the tree arranged in left-to-right order. For example,
(define x (list (list 1 2) (list 3 4)))
(fringe x)
(1 2 3 4)
(fringe (list x x))
(1 2 3 4 1 2 3 4)
A binary mobile consists of two branches, a left branch and a right
branch. Each branch is a rod of a certain length, from which hangs
either a weight or another binary mobile. We can represent a binary
mobile using compound data by constructing it from two branches (for
example, using list):
(define (make-mobile left right)
(list left right))
A branch is constructed from a length (which must be a number) together with a structure, which may be either a number (representing a simple weight) or another mobile:
(define (make-branch length structure)
(list length structure))
- Write the corresponding selectors
left-branch and
right-branch, which return the branches of a mobile, and
branch-length and branch-structure, which return the components of a branch.
- Using your selectors, define a procedure
total-weight
that returns the total weight of a mobile.
- A mobile is said to be balanced if the torque applied
by its top-left branch is equal to that applied by its top-right
branch (that is, if the length of the left rod multiplied by the
weight hanging from that rod is equal to the corresponding product for
the right side) and if each of the submobiles hanging off its branches
is balanced. Design a predicate that tests whether a binary mobile is balanced.
Suppose we change the representation of mobiles so that the constructors are
(define (make-mobile left right)
(cons left right))
(define (make-branch length structure)
(cons length structure))
How much do you need to change your programs to convert to the new representation?
Define a procedure square-tree analogous to the square-list procedure of exercise 2.21. That is, square-list should behave as follows:
(square-tree
(list 1
(list 2 (list 3 4) 5)
(list 6 7)))
(1 (4 (9 16) 25) (36 49))
Define square-tree both directly (i.e., without using any
higher-order procedures) and also by using map and recursion.
Abstract your answer to exercise 2.30 to produce a procedure tree-map with the property that square-tree could be defined as
(define (square-tree tree) (tree-map square tree))
We can represent a set as a list of distinct elements, and we can
represent the set of all subsets of the set as a list of lists. For
example, if the set is (1 2 3), then the set of all subsets is (() (3) (2) (2 3) (1) (1 3) (1 2) (1 2 3)). Complete the following definition of a procedure that generates the set of subsets of a set and give a clear explanation of why it works:
(define (subsets s)
(if (null? s)
(list nil)
(let ((rest (subsets (cdr s))))
(append rest (map <??> rest)))))
Mapping over trees
Just as map is a powerful abstraction for dealing with sequences, map together with recursion is a powerful abstraction for dealing with trees. For instance, the scale-tree procedure, analogous to scale-list of
section 2.2.1 takes as arguments a numeric factor and a tree whose leaves are numbers. It returns a tree of the same shape,
where each number is multiplied by the factor. The recursive plan for scale-tree is similar to the one for
count-leaves:
(define (scale-tree tree factor)
(cond ((null? tree) nil)
((not (pair? tree)) (* tree factor))
(else (cons (scale-tree (car tree) factor)
(scale-tree (cdr tree) factor)))))
(scale-tree (list 1 (list 2 (list 3 4) 5) (list 6 7))
10)
(10 (20 (30 40) 50) (60 70))
Another way to implement scale-tree is to regard the
tree as a sequence of sub-trees and use map. We map
over the sequence, scaling each sub-tree in turn, and return the list
of results. In the base case, where the tree is a leaf, we simply
multiply by the factor:
(define (scale-tree tree factor)
(map (lambda (sub-tree)
(if (pair? sub-tree)
(scale-tree sub-tree factor)
(* sub-tree factor)))
tree))
Many tree operations can be implemented by similar combinations of
sequence operations and recursion.
Suppose we evaluate the expression (list 1 (list 2 (list 3 4))). Give the result printed by the interpreter, the corresponding
box-and-pointer structure, and the interpretation of this as a tree (as in figure 2.6).
Give combinations of cars and cdrs that will pick 7 from
each of the following lists:
(1 3 (5 7) 9)
((7))
(1 (2 (3 (4 (5 (6 7))))))
Suppose we define x and y to be two lists:
(define x (list 1 2 3))
(define y (list 4 5 6))
What result is printed by the interpreter in response to evaluating
each of the following expressions:
(append x y)
(cons x y)
(list x y)
Modify your reverse procedure of exercise 2.18 to
produce a deep-reverse procedure that takes a list as argument and returns as its value the list with its elements reversed and with
all sublists deep-reversed as well. For example,
(define x (list (list 1 2) (list 3 4)))
x
((1 2) (3 4))
(reverse x)
((3 4) (1 2))
(deep-reverse x)
((4 3) (2 1))
Write a procedure fringe that takes as argument a tree
(represented as a list) and returns a list whose elements are all the
leaves of the tree arranged in left-to-right order. For example,
(define x (list (list 1 2) (list 3 4)))
(fringe x)
(1 2 3 4)
(fringe (list x x))
(1 2 3 4 1 2 3 4)
A binary mobile consists of two branches, a left branch and a right
branch. Each branch is a rod of a certain length, from which hangs
either a weight or another binary mobile. We can represent a binary
mobile using compound data by constructing it from two branches (for
example, using list):
(define (make-mobile left right)
(list left right))
A branch is constructed from a length (which must be a number) together with a structure, which may be either a number (representing a simple weight) or another mobile:
(define (make-branch length structure)
(list length structure))
- Write the corresponding selectors
left-branch and
right-branch, which return the branches of a mobile, and
branch-length and branch-structure, which return the components of a branch.
- Using your selectors, define a procedure
total-weight
that returns the total weight of a mobile.
- A mobile is said to be balanced if the torque applied
by its top-left branch is equal to that applied by its top-right
branch (that is, if the length of the left rod multiplied by the
weight hanging from that rod is equal to the corresponding product for
the right side) and if each of the submobiles hanging off its branches
is balanced. Design a predicate that tests whether a binary mobile is balanced.
Suppose we change the representation of mobiles so that the
constructors are
(define (make-mobile left right)
(cons left right))
(define (make-branch length structure)
(cons length structure))
How much do you need to change your programs to convert to the new representation?
Define a procedure square-tree analogous to the square-list procedure of exercise 2.21. That is, square-list should behave as follows:
(square-tree
(list 1
(list 2 (list 3 4) 5)
(list 6 7)))
(1 (4 (9 16) 25) (36 49))
Define square-tree both directly (i.e., without using any
higher-order procedures) and also by using map and recursion.
Abstract your answer to exercise 2.30 to produce a procedure tree-map with the property that square-tree could be defined as
(define (square-tree tree) (tree-map square tree))
We can represent a set as a list of distinct elements, and we can
represent the set of all subsets of the set as a list of lists. For
example, if the set is (1 2 3), then the set of all subsets is (() (3) (2) (2 3) (1) (1 3) (1 2) (1 2 3)). Complete the following definition of a procedure that generates the set of subsets of a set and give a clear explanation of why it works:
(define (subsets s)
(if (null? s)
(list nil)
(let ((rest (subsets (cdr s))))
(append rest (map <??> rest)))))
Comments
Post new comment