; CSE341, Winter 2013
; CSE341 Spring 2013
; Lecture 13: Racket Introduction
; always make this the first (non-comment, non-blank) line of your file
#lang racket
; not needed here, but a workaround so we could write tests in a second file
; see getting-started-with-Racket instructions for more explanation
(provide (all-defined-out))
; basic definitions
(define three 3)
(define five (+ three 2)) ; function call is (e1 e2 ... en): parens matter!
; basic function
(define cube1
(lambda (x)
(* x (* x x))))
; many functions, such as *, take a variable number of arguments
(define cube2
(lambda (x)
(* x x x)))
; syntactic sugar for function definitions
(define (cube3 x)
(* x x x))
; conditional
(define (pow1 x y)
(if (= y 0)
1
(* x (pow1 x (- y 1)))))
; currying
(define pow2
(lambda (x)
(lambda (y)
(pow1 x y))))
; sugar for currying (fairly new to Racket)
(define ((pow2b x) y) (pow1 x y))
(define three-to-the (pow2 3))
(define eightyone (three-to-the 4))
(define sixteen ((pow2 2) 4)) ; need exactly these parens
; list processing: null, cons, null?, car, cdr
; we won't use pattern-matching in Racket
(define (sum xs)
(if (null? xs)
0
(+ (car xs) (sum (cdr xs)))))
(define (my-append xs ys) ; same as append already provided
(if (null? xs)
ys
(cons (car xs) (my-append (cdr xs) ys))))
(define (my-map f xs) ; same as map already provided
(if (null? xs)
null
(cons (f (car xs)) (my-map f (cdr xs)))))
(define foo (my-map (lambda (x) (+ x 1)) (cons 3 (cons 4 (cons 5 null)))))
; [first big difference from ML (and Java)] PARENS MATTER!!
(define (fact n) (if (= n 0) 1 (* n (fact (- n 1)))))
; base case calls the function 1 with zero arguments
(define (fact-wrong1 n) (if (= n 0) (1) (* n (fact-wrong1 (- n 1)))))
; so why does this work (hint: it's not recursive
; and there is no type system):
(define (fact-works1b n) (if (= n 0) (1) (* n (fact (- n 1)))))
; passing 5 arguments to if: =, n, 0, 1, (* ...)
; this is bad syntax
;(define (fact-wrong2 n) (if = n 0 1 (* n (fact-wrong2 (- n 1)))))
; calling n with zero arguments and also having an if
; this is not a legal definition: bad syntax
;(define fact-wrong3 (n) (if (= n 0) 1 (* n (fact-wrong3 (- n 1)))))
; calling multiply with three arguments, which would be fine
; except the second one is fact-wrong4
(define (fact-wrong4 n) (if (= n 0) 1 (* n fact-wrong4 (- n 1))))
; calling fact-wrong5 with zero arguments, calling result of that
; with n-1
(define (fact-wrong5 n) (if (= n 0) 1 (* n ((fact-wrong5) (- n 1)))))
; treating n as a function of two arguments, passing it *
(define (fact-wrong6 n) (if (= n 0) 1 (n * (fact-wrong6 (- n 1)))))
; [second big difference from ML (and Java)] Dynamic Typing!!
; dynamic typing: can use values of any type anywhere
; e.g., a list that holds numbers or other lists
; this function sums lists of (numbers or lists of (numbers or ...)),
; but it does assume it only encounters lists or numbers (else run-time error)
(define (sum1 xs)
(if (null? xs)
0
(if (number? (car xs))
(+ (car xs) (sum1 (cdr xs)))
(+ (sum1 (car xs)) (sum1 (cdr xs))))))
; this version does not fail on non-lists -- it treats them as 0
(define (sum2 xs)
(if (null? xs)
0
(if (number? (car xs))
(+ (car xs) (sum2 (cdr xs)))
(if (list? (car xs))
(+ (sum2 (car xs)) (sum2 (cdr xs)))
(sum2 (cdr xs))))))
; better style: use cond instead of nested ifs
; sum3 is equivalent to sum1 above but better style
(define (sum3 xs)
(cond [(null? xs) 0]
[(number? (car xs)) (+ (car xs)(sum3 (cdr xs)))]
[#t (+ (sum3 (car xs)) (sum3 (cdr xs)))]))
; sum4 is equivalent to sum2 above but better style
(define (sum4 xs)
(cond [(null? xs) 0]
[(number? xs) xs]
[(list? xs) (+ (sum4 (car xs)) (sum4 (cdr xs)))]
[#t 0]))
; this function counts how many #f are in a (non-nested) list
; it uses the "controversial" idiom of anything not #f is true
(define (count-falses xs)
(cond [(null? xs) 0]
[(car xs) (count-falses (cdr xs))] ; (car xs) can have any type
[#t (+ 1 (count-falses (cdr xs)))]))
; different kinds of local bindings
(define (max-of-list xs)
(cond [(null? xs) (error "max-of-list given empty list")]
[(null? (cdr xs)) (car xs)]
[#t (let ([tlans (max-of-list (cdr xs))])
(if (> tlans (car xs))
tlans
(car xs)))]))
; let evaluates all expressions using outer environment,
; *not* earlier bindings
(define (double1 x)
(let ([x (+ x 3)]
[y (+ x 2)])
(+ x y -5)))
; let* is like ML's let: environment includes previous bindings
(define (double2 x)
(let* ([x (+ x 3)]
[y (+ x 2)])
(+ x y -8)))
; letrec uses an environment where all bindings in scope
; * like ML's use of and for mutual recursion
; * you get # if you use a variable before it's defined
; where as always function bodies not used until called
; (bindings still evaluated in order)
(define (triple x)
(letrec ([y (+ x 2)]
[f (lambda (z) (+ z y w x))]
[w (+ x 7)])
(f -9)))
(define (mod2 x)
(letrec
([even?(lambda (x) (if (zero? x) #t (odd? (- x 1))))]
[odd? (lambda (x) (if (zero? x) #f (even? (- x 1))))])
(if (even? x) 0 1)))
(define (bad-letrec-example x)
(letrec ([y z] ; okay to be a lambda that uses z, but here y undefined
[z 13])
(if x y z)))
; and you can use define locally (in some positions)
; the same as letrec when binding local variables
(define (mod2_b x)
(define even? (lambda(x)(if (zero? x) #t (odd? (- x 1)))))
(define odd? (lambda(x)(if (zero? x) #f (even? (- x 1)))))
(if (even? x) 0 1))
; at the top-level (*)
; same letrec-like rules: can have forward references, but
; definitions still evaluate in order and cannot be repeated
; (*) we are not actually at top-level -- we are in a module called lec13.rkt
(define (f x) (+ x (* x y))) ; forward reference okay here
(define y 3)
(define z (+ y 4)) ; backward reference okay
;(define w (+ v 4)) ; not okay (get an error instead of #)
(define v 5)
;(define f 17) ; not okay: f already defined in this module
(define b 3)
(define g (lambda (x) (* 1 (+ x b))))
(define c (+ b 4))
(set! b 5)
(define d (g 4))
(define e c)
; the truth about cons: it just makes a pair
(define pr (cons 1 (cons #t "hi")))
(define lst (cons 1 (cons #t (cons "hi" null))))
(define hi (cdr (cdr pr)))
(define hi-again (car (cdr (cdr lst))))
(define hi-again-shorter (caddr lst))
(define no (list? pr))
(define yes (pair? pr))
(define of-course (and (list? lst) (pair? lst)))
; (define do-not-do-this (length pr))
; cons cells are immutable -- this does not change a cell's contents
(define lst1 (cons 14 null))
(define aliased_lst1 lst1)
(set! lst1 (cons 42 null))
(define fourteen (car aliased_lst1))
; but since mutable pairs are useful, Racket has them too:
; mcons, mcar, mcdr, set-mcar!, set-mcdr!
(define mpr (mcons 1 (mcons #t "hi")))
(set-mcdr! (mcdr mpr) "bye")
(define bye (mcdr (mcdr mpr)))
; Note: run-time error to use mcar on a cons or car on an mcons