# Multiplication of Binary List in Scheme

I'm trying to implement an algorithm to multiply two bit-lists of 1s and 0s as a simulation to binary multiplication. It should return a like list, but I am having a hard time building on what I already have. Some help would be appreciated...

``````;;Function designed to accept two bit-list binary numbers (reverse order) and produce their product, a bitlist in reverse order.
;;Example: (multiply '(0 1 1 0 1) '(1 0 1)) should produce '(0 1 1 1 0 1 1)
(define (multiply x y)
(cond
;[(= null? y) 0]
[(zero? y) 0]
(#t (let ((z (multiply  x (rest y )))) (cond
[(num_even? y) (cons 0 z)]
(#t (addWithCarry x (cons 0 z) 1)))))))

;This is to check if the current value of parameter x is the number 0
(define (zero? x)
(cond
((null? x) #t)
((=(first x) 1) #f)
(#t (zero? (rest x)))))

;This is to check if the current parameter x is 0 (even) or not.
(define (num_even? x)
(cond
[(null? x) #t]
[(=(first x) 0)#t]
[#t (num_even? (rest x))]))
(cond
((and (null? x) (null? y)) (if (= carry 0) '( ) '(1)))
((null? x) (addWithCarry '(0) y carry))
((null? y) (addWithCarry x '(0) carry))
(#t (let ((bit1 (first x))
(bit2 (first y)))
(cond
((=(+ bit1 bit2 carry) 0) (cons 0 (addWithCarry (rest x)(rest y) 0)))
((=(+ bit1 bit2 carry) 1) (cons 1 (addWithCarry (rest x)(rest y) 0)))
((=(+ bit1 bit2 carry) 2) (cons 0 (addWithCarry (rest x)(rest y) 1)))
(#t (cons 1 (addWithCarry (rest x) (rest y) 1))))))))
``````
-
If `multiply` should return a list, then the clause `[(zero? y) 0]` is wrong; it doesn't return a list. And if `multiply` returns a list, then `z` is a list, then `(* 10 z)` and `(+ x (* 10 z))` will be errors. – Joshua Taylor Nov 19 '13 at 18:06
As a general stylistic note, there's no reason to do something like `if boolean-condition then true else false`, you'd just do `boolean-condition`. Similarly, the body of your `zero?` procedure can just be `(or (null? x) (and (not (= (first x) 1)) (zero? (rest x))))`. – Joshua Taylor Nov 19 '13 at 18:11
It's not clear what `num_even?` is supposed to do (comments would help!), but the same thing applies to it; it can be simplified as `(or (null? x) (= (first x) 0) (num_even? (rest x)))`. – Joshua Taylor Nov 19 '13 at 18:12
What's the specific problem here? You've shown some code, but not what it produces, nor what it ought to produce. "Questions concerning problems with code you've written must describe the specific problem … Questions asking for code must demonstrate a minimal understanding of the problem being solved. Include attempted solutions, why they didn't work, and the expected results." – Joshua Taylor Nov 19 '13 at 18:17
what's the data structure look like for your binary data – WorBlux Nov 19 '13 at 21:01

Based on my previous answer for a base-10 multiplication, here's a solution that works for binary numbers (in the correct order):

``````(define base 2)

(define (car0 lst)
(if (empty? lst)
0
(car lst)))

(define (cdr0 lst)
(if (empty? lst)
empty
(cdr lst)))

(let loop ((l1 (reverse l1))
(l2 (reverse l2))
(carry 0)
(res '()))
(if (and (null? l1) (null? l2) (= 0 carry))
res
(let* ((d1 (car0 l1))
(d2 (car0 l2))
(loop (cdr0 l1)
(cdr0 l2)
(cons dn res))))))

(define (mult1 n lst) ; multiply a list by one digit
(let loop ((lst (reverse lst))
(carry 0)
(res '()))
(if (and (null? lst) (= 0 carry))
res
(let* ((c (car0 lst))
(m (+ (* n c) carry))
(m0 (modulo m base)))
(loop (cdr0 lst)
(quotient (- m m0) base)
(cons m0 res))))))

(define (apa-multi l1 l2) ; full multiplication
(let loop ((l2 (reverse l2))
(app '())
(res '()))
(if (null? l2)
res
(let* ((d2 (car l2))
(m (mult1 d2 l1))
(r (append m app)))
(loop (cdr l2)
(cons '0 app)
``````(apa-multi '(1 0 1 1 0) '(1 0 1))