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CSC135-Assignment 2 Scheme Functions Solved
Write the following Scheme Functions:
A. "appendInt" - takes two positive integers N and M, and returns an integer
where M is tacked on the end of N.
For example:
(appendInt 124 80534) will return 12480534
(appendInt 2479 9634) will return 24799634
(appendInt 5 456) will return 5456.
B. "listsMax" - takes two lists of integers of the same length, and returns a list
where the elements are the max value of the two elements in the same position
of each list. You may assume that the two input lists are the same length.
For example:
(listsMax ‘(2 5 11 25 9) ‘(2 9 10 20 12)) will return ‘(2 9 11 25 12)
(listsMax ‘(3 4 3 8) ‘(7 5 6 2)) will return ‘(7 5 6 8)
C. "cycler" - takes a list L and an integer N, and returns an integer which is the
result of "cycling" N through the list L. "Cycling" is done by successively
applying the operations addition (+), subtraction (-) and multiplication (*) using
each of the integers in L until they are exhausted. If the length of L is longer
than 3, then the +, -, and * operations repeat. You may assume that the list L
has at least one number in it.
For example:
(cycler '(3 8 2 6 4 5 5) 28) returns 245, because:
28 + 3 = 31
31 - 8 = 23
23 * 2 = 46
46 + 6 = 52
52 - 4 = 48
48 * 5 = 240
240 + 5 = 245
D. "functionWinner" - takes as input a Boolean function F, and two lists L and M.
It returns:
the number 1 if list L is the "winner"
the number 2 if list M is the "winner"
the number 0 if the two lists are tied
The "winning" list is the one for which the function F has the most "true" answers
among the values in the two lists.
For example:
(functionWinner isNeg ‘(8 -4 3 8) '(7 -3 -2 1 -5)) returns 2,
because the second list has more negative numbers than the first list.
(functionWinner isEven ‘(8 -4 3 8) '(6 3 2 1 -4)) returns 0,
because the two lists have the same number of evens in them.
E. "countTrue" - takes a list L (which may include sublists) and a Boolean function F,
and returns a count of the number of elements in the list for which F returns true.
Elements nested in sublists are included. You only need to handle functions F defined
for scalar inputs. For example:
(countTrue ‘(3 (2 1 -5) 6 (7 (2 (-3) 5))) isOdd) will return 6
(countTrue ‘(3 (2 1 -5) 6 (7 (2 (-3) 5))) isNeg) will return 2
F. "badNumberRemover" - takes a list L that contains only numbers.
It then builds a "remover" function based on L.
The resulting "remover" function can take a list of numbers, and return an identical
list except that the "bad" numbers have been removed. The "bad" numbers are any of
those that were specified in the original list L.
For example, if badNumberRemover was called as follows:
(define B (badNumberRemover '(42 13 4)))
then the produced function B would behave as follows:
(B '(83 2 17 42 9 100 42 13 17 29)) would return (83 2 17 9 100 17 29)
Your task is to write badNumberRemover, not P.
You will probably find it useful to write one or more utility functions.
Of course, badNumberRemover should work for any reasonable input list L,
not just the one shown above.
A. "appendInt" - takes two positive integers N and M, and returns an integer
where M is tacked on the end of N.
For example:
(appendInt 124 80534) will return 12480534
(appendInt 2479 9634) will return 24799634
(appendInt 5 456) will return 5456.
B. "listsMax" - takes two lists of integers of the same length, and returns a list
where the elements are the max value of the two elements in the same position
of each list. You may assume that the two input lists are the same length.
For example:
(listsMax ‘(2 5 11 25 9) ‘(2 9 10 20 12)) will return ‘(2 9 11 25 12)
(listsMax ‘(3 4 3 8) ‘(7 5 6 2)) will return ‘(7 5 6 8)
C. "cycler" - takes a list L and an integer N, and returns an integer which is the
result of "cycling" N through the list L. "Cycling" is done by successively
applying the operations addition (+), subtraction (-) and multiplication (*) using
each of the integers in L until they are exhausted. If the length of L is longer
than 3, then the +, -, and * operations repeat. You may assume that the list L
has at least one number in it.
For example:
(cycler '(3 8 2 6 4 5 5) 28) returns 245, because:
28 + 3 = 31
31 - 8 = 23
23 * 2 = 46
46 + 6 = 52
52 - 4 = 48
48 * 5 = 240
240 + 5 = 245
D. "functionWinner" - takes as input a Boolean function F, and two lists L and M.
It returns:
the number 1 if list L is the "winner"
the number 2 if list M is the "winner"
the number 0 if the two lists are tied
The "winning" list is the one for which the function F has the most "true" answers
among the values in the two lists.
For example:
(functionWinner isNeg ‘(8 -4 3 8) '(7 -3 -2 1 -5)) returns 2,
because the second list has more negative numbers than the first list.
(functionWinner isEven ‘(8 -4 3 8) '(6 3 2 1 -4)) returns 0,
because the two lists have the same number of evens in them.
E. "countTrue" - takes a list L (which may include sublists) and a Boolean function F,
and returns a count of the number of elements in the list for which F returns true.
Elements nested in sublists are included. You only need to handle functions F defined
for scalar inputs. For example:
(countTrue ‘(3 (2 1 -5) 6 (7 (2 (-3) 5))) isOdd) will return 6
(countTrue ‘(3 (2 1 -5) 6 (7 (2 (-3) 5))) isNeg) will return 2
F. "badNumberRemover" - takes a list L that contains only numbers.
It then builds a "remover" function based on L.
The resulting "remover" function can take a list of numbers, and return an identical
list except that the "bad" numbers have been removed. The "bad" numbers are any of
those that were specified in the original list L.
For example, if badNumberRemover was called as follows:
(define B (badNumberRemover '(42 13 4)))
then the produced function B would behave as follows:
(B '(83 2 17 42 9 100 42 13 17 29)) would return (83 2 17 9 100 17 29)
Your task is to write badNumberRemover, not P.
You will probably find it useful to write one or more utility functions.
Of course, badNumberRemover should work for any reasonable input list L,
not just the one shown above.
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