slime/bin/tests/sicp.slime

(define (abs x)
  (cond ((< x 0) (- x))
        (else x)))

(assert (= (abs 1) 1))
(assert (= (abs (- 2)) 2))


(define (abs x)
  (if (< x 0)
      (- x)
    x))

(assert (= (abs 12) 12))
(assert (= (abs (- 32)) 32))


(define (>= x y)
  (or (> x y)
      (= x y)))

(assert (>= 2 2))
(assert (>= 3 2))
(assert (not (>= 1 2)))
(assert (not (>= 12 44)))


(define (>= x y)
  (not (< x y)))

(assert (>= 2 2))
(assert (>= 3 2))
(assert (not (>= 1 2)))
(assert (not (>= 12 44)))


(define (a-plus-abs-b a b)
  ((if (> b 0) + -) a b))

(assert (= (a-plus-abs-b 1  2) 3))
(assert (= (a-plus-abs-b 1 -2) 3))

(define (square x) (* x x))
(define (cube x) (* x x x))

(assert (= ((lambda (x y z)
              (+ x y (square z)))
            1 2 3)
           12))

;; ;;; --------------------
;; ;;;    newtons method
;; ;;; --------------------

(define tolerance 0.001)

(define (square x)
  (* x x))

(define (average x y)
  (/ (+ x y) 2))

(define (improve guess x)
  (average guess (/ x guess)))

(define (good-enough? guess x)
  (< (abs (- (square guess) x)) tolerance))

(define (sqrt-iter guess x)
  (if (good-enough? guess x)
      guess
    (sqrt-iter (improve guess x) x)))

(define (sqrt x)
  (sqrt-iter 1.0 x))

(define (sqrt2 x)
  (define (good-enough? guess x)
    (< (abs (- (square guess) x)) 0.001))

  (define (improve guess x)
    (average guess (/ x guess)))

  (define (sqrt-iter guess x)
    (if (good-enough? guess x)
        guess
      (sqrt-iter (improve guess x) x)))

  (sqrt-iter 1.0 x))

(define (sqrt3 x)
  (define (good-enough? guess)
    (< (abs (- (square guess) x)) 0.001))

  (define (improve guess)
    (average guess (/ x guess)))

  (define (sqrt-iter guess)
    (if (good-enough? guess)
        guess
      (sqrt-iter (improve guess))))

  (sqrt-iter 1.0))

(assert      (< (abs (- 3 (sqrt 9)))  tolerance))
(assert      (< (abs (- 4 (sqrt 16))) tolerance))
(assert (not (< (abs (- 4 (sqrt 15))) tolerance)))

(assert      (< (abs (- 3 (sqrt2 9)))  tolerance))
(assert      (< (abs (- 4 (sqrt2 16))) tolerance))
(assert (not (< (abs (- 4 (sqrt2 15))) tolerance)))

(assert      (< (abs (- 3 (sqrt3 9)))  tolerance))
(assert      (< (abs (- 4 (sqrt3 16))) tolerance))
(assert (not (< (abs (- 4 (sqrt3 15))) tolerance)))


;;; -----------------
;;;     factorial
;;; -----------------

(define (factorial n)
  (if (= n 1)
      1
    (* n (factorial (- n 1)))))

(define (factorial2 n)
  (fact-iter 1 1 n))

(define (fact-iter product counter max-count)
  (if (> counter max-count)
      product
    (fact-iter (* counter product) (+ counter 1) max-count)))

(define (factorial3 n)
  (define (iter product counter)
    (if (> counter n)
        product
      (iter (* counter product) (+ counter 1))))

  (iter 1 1))

(assert (= (factorial  6) 720))
(assert (= (factorial2 6) 720))
(assert (= (factorial3 6) 720))

;;; ----------------
;;;     ackermann
;;; ----------------

(define (A m n)
    (cond ((= m 0) (+ n 1))
          ((= n 0) (A (- m 1) 1))
          (else (A (- m 1) (A m (- n 1))))))

(assert (= (A 0 0) 1))
(assert (= (A 1 2) 4))
(assert (= (A 3 1) 13))


;; ;;; ---------------
;; ;;;    Fibonacci
;; ;;; ---------------

(define (fib n)
  (cond ((= n 0) 0)
        ((= n 1) 1)
        (else (+ (fib (- n 1)) (fib (- n 2))))))

(define (fib2 n)
  (fib-iter 1 0 n))

(define (fib-iter a b count)
  (if (= count 0)
      b
    (fib-iter (+ a b) a (- count 1))))

(assert (= (fib 2) 1))
(assert (= (fib 3) 2))
(assert (= (fib 4) 3))
(assert (= (fib 5) 5))
(assert (= (fib 6) 8))

(assert (= (fib2 2) 1))
(assert (= (fib2 3) 2))
(assert (= (fib2 4) 3))
(assert (= (fib2 5) 5))
(assert (= (fib2 6) 8))

;;; ------------------
;;;    count change
;;; ------------------

(define (count-change amount)
  (define (cc amount kinds-of-coins)
    (cond ((= amount 0) 1)
          ((or (< amount 0) (= kinds-of-coins 0)) 0)
          (else (+ (cc amount (- kinds-of-coins 1))
                   (cc (- amount (first-denomination kinds-of-coins)) kinds-of-coins)))))

  (define (first-denomination kinds-of-coins)
    (cond ((= kinds-of-coins 1) 1)
          ((= kinds-of-coins 2) 5)
          ((= kinds-of-coins 3) 10)
          ((= kinds-of-coins 4) 25)
          ((= kinds-of-coins 5) 50)))

  (cc amount 5))

;; (assert (= (count-change 100) 292))

;; ;;; --------------------
;; ;;;    exponentiation
;; ;;; --------------------

(define (expt b n)
  (if (= n 0)
      1
    (* b (expt b (- n 1)))))

(define (expt2 b n)
  (define (expt-iter b counter product)
    (if (= counter 0)
        product
      (expt-iter b (- counter 1) (* b product))))

  (expt-iter b n 1))

(define (fast-expt b n)
  (define (even? n)
    (= (% n 2) 0))

  (cond ((= n 0) 1)
        ((even? n) (square (fast-expt b (/ n 2))))
        (else (* b (fast-expt b (- n 1))))))

(assert (= (expt 1 2) 1))
(assert (= (expt 2 2) 4))
(assert (= (expt 2 3) 8))

(assert (= (expt2 1 2) 1))
(assert (= (expt2 2 2) 4))
(assert (= (expt2 2 3) 8))

(assert (= (fast-expt 1 2) 1))
(assert (= (fast-expt 2 2) 4))
(assert (= (fast-expt 2 3) 8))

;;; ----------
;;;    gcd
;;; ----------

(define (gcd a b)
  (if (= b 0)
      a
    (gcd b (% a b))))

(assert (= (gcd 40 6) 2))
(assert (= (gcd 13 4) 1))


;;; ----------
;;;   primes
;;; ----------

(define (smallest-divisor n)
  (find-divisor n 2))

(define (find-divisor n test-divisor)
  (cond ((> (square test-divisor) n) n)
        ((divides? test-divisor n) test-divisor)
        (else (find-divisor n (+ test-divisor 1)))))

(define (divides? a b)
  (= (% b a) 0))

(define (prime? n)
  (= n (smallest-divisor n)))

(assert (prime? 13))
(assert (prime? 11))
(assert (not (prime? 12)))


;; ----------------------
   ;; simple integral
;; ----------------------

(define (sum term a next b)
  (if (> a b)
      0
    (+ (term a) (sum term (next a) next b))))

(define (integral f a b dx)
  (define (add-dx x) (+ x dx))
  (* (sum f (+ a (/ dx 2.0)) add-dx b) dx))

(define (pi-sum a b)
  (define (pi-term x) (/ 1.0 (* x (+ x 2))))
  (define (pi-next x) (+ x 4))
  (sum pi-term a pi-next b))

(assert (< (abs (- (* 8 (pi-sum 1 100))     3.121595)) 0.0001))
(assert (< (abs (- (integral cube 0 1 0.02) 0.249950)) 0.0001))


;; ------------------------------------------------------------
      ;; F(x,y) = x(1 + xy)^2 + y(1 − y) + (1 + xy)(1 − y)
;; ------------------------------------------------------------

(define (f x y)
  (let ((a (+ 1 (* x y)))
        (b (- 1 y)))
    (+ (* x (square a))
       (* y b)
       (* a b))))

(assert (= (f 0 0) 1))
(assert (= (f 1 1) 4))


;;; ---------------
;;;    find zero
;;; ---------------

(define (positive? x) (< 0 x))
(define (negative? x) (< x 0))

(define (search f neg-point pos-point)
  (let ((midpoint (average neg-point pos-point)))
    (if (close-enough? neg-point pos-point)
        midpoint
      (let ((test-value (f midpoint)))
        (cond ((positive? test-value) (search f neg-point midpoint))
              ((negative? test-value) (search f midpoint pos-point))
              (else midpoint))))))

(define (close-enough? x y) (< (abs (- x y)) 0.001))

(assert (close-enough? (search (lambda (x) (- 1 (square x))) -3 3) -1))