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518 lines
17 KiB
Markdown
518 lines
17 KiB
Markdown
---
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language: "CHICKEN"
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filename: CHICKEN.scm
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contributors:
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- ["Diwakar Wagle", "https://github.com/deewakar"]
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---
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CHICKEN is an implementation of Scheme programming language that can
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compile Scheme programs to C code as well as interpret them. CHICKEN
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supports R5RS and R7RS (work in progress) standards and many extensions.
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```scheme
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;; #!/usr/bin/env csi -s
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;; Run the CHICKEN REPL in the commandline as follows :
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;; $ csi
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 0. Syntax
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; Single line comments start with a semicolon
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#| Block comments
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can span multiple lines and...
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#| can be nested
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|#
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|#
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;; S-expression comments are used to comment out expressions
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#; (display "nothing") ; discard this expression
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;; CHICKEN has two fundamental pieces of syntax: Atoms and S-expressions
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;; an atom is something that evaluates to itself
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;; all builtin data types viz. numbers, chars, booleans, strings etc. are atoms
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;; Furthermore an atom can be a symbol, an identifier, a keyword, a procedure
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;; or the empty list (also called null)
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'athing ;; => athing
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'+ ;; => +
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+ ;; => <procedure C_plus>
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;; S-expressions (short for symbolic expressions) consists of one or more atoms
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(quote +) ;; => + ; another way of writing '+
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(+ 1 2 3) ;; => 6 ; this S-expression evaluates to a function call
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'(+ 1 2 3) ;; => (+ 1 2 3) ; evaluates to a list
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 1. Primitive Datatypes and Operators
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; Numbers
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99999999999999999999 ;; integers
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#b1010 ;; binary ; => 10
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#o10 ;; octal ; => 8
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#x8ded ;; hexadecimal ; => 36333
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3.14 ;; real
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6.02e+23
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3/4 ;; rational
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;;Characters and Strings
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#\A ;; A char
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"Hello, World!" ;; strings are fixed-length arrays of characters
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;; Booleans
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#t ;; true
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#f ;; false
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;; Function call is written as (f x y z ...)
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;; where f is a function and x,y,z, ... are arguments
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(print "Hello, World!") ;; => Hello, World!
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;; formatted output
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(printf "Hello, ~a.\n" "World") ;; => Hello, World.
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;; print commandline arguments
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(map print (command-line-arguments))
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(list 'foo 'bar 'baz) ;; => (foo bar baz)
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(string-append "pine" "apple") ;; => "pineapple"
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(string-ref "tapioca" 3) ;; => #\i;; character 'i' is at index 3
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(string->list "CHICKEN") ;; => (#\C #\H #\I #\C #\K #\E #\N)
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(string-intersperse '("1" "2") ":") ;; => "1:2"
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(string-split "1:2:3" ":") ;; => ("1" "2" "3")
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;; Predicates are special functions that return boolean values
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(atom? #t) ;; => #t
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(symbol? #t) ;; => #f
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(symbol? '+) ;; => #t
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(procedure? +) ;; => #t
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(pair? '(1 2)) ;; => #t
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(pair? '(1 2 . 3)) ;; => #t
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(pair? '()) ;; => #f
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(list? '()) ;; => #t
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;; Some arithmetic operations
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(+ 1 1) ;; => 2
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(- 8 1) ;; => 7
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(* 10 2) ;; => 20
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(expt 2 3) ;; => 8
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(remainder 5 2) ;; => 1
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(/ 35 5) ;; => 7
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(/ 1 3) ;; => 0.333333333333333
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 2. Variables
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; You can create variables with define
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;; A variable name can use any character except: ()[]{}",'`;#\
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(define myvar 5)
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myvar ;; => 5
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;; Alias to a procedure
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(define ** expt)
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(** 2 3) ;; => 8
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;; Accessing an undefined variable raises an exception
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s ;; => Error: unbound variable: s
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;; Local binding
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(let ((me "Bob"))
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(print me)) ;; => Bob
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(print me) ;; => Error: unbound variable: me
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;; Assign a new value to previously defined variable
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(set! myvar 10)
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myvar ;; => 10
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 3. Collections
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; Pairs
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;; 'cons' constructs pairs,
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;; 'car' extracts the first element, 'cdr' extracts the rest of the elements
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(cons 'subject 'verb) ;; => '(subject . verb)
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(car (cons 'subject 'verb)) ;; => subject
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(cdr (cons 'subject 'verb)) ;; => verb
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;; Lists
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;; cons creates a new list if the second item is a list
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(cons 0 '()) ;; => (0)
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(cons 1 (cons 2 (cons 3 '()))) ;; => (1 2 3)
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;; 'list' is a convenience variadic constructor for lists
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(list 1 2 3) ;; => (1 2 3)
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;; Use 'append' to append lists together
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(append '(1 2) '(3 4)) ;; => (1 2 3 4)
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;; Some basic operations on lists
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(map add1 '(1 2 3)) ;; => (2 3 4)
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(reverse '(1 3 4 7)) ;; => (7 4 3 1)
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(sort '(11 22 33 44) >) ;; => (44 33 22 11)
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(define days '(SUN MON FRI))
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(list-ref days 1) ;; => MON
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(set! (list-ref days 1) 'TUE)
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days ;; => (SUN TUE FRI)
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;; Vectors
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;; Vectors are heterogeneous structures whose elements are indexed by integers
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;; A Vector typically occupies less space than a list of the same length
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;; Random access of an element in a vector is faster than in a list
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#(1 2 3) ;; => #(1 2 3) ;; literal syntax
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(vector 'a 'b 'c) ;; => #(a b c)
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(vector? #(1 2 3)) ;; => #t
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(vector-length #(1 (2) "a")) ;; => 3
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(vector-ref #(1 (2) (3 3)) 2);; => (3 3)
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(define vec #(1 2 3))
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(vector-set! vec 2 4)
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vec ;; => #(1 2 4)
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;; Vectors can be created from lists and vice-verca
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(vector->list #(1 2 4)) ;; => '(1 2 4)
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(list->vector '(a b c)) ;; => #(a b c)
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 4. Functions
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; Use 'lambda' to create functions.
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;; A function always returns the value of its last expression
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(lambda () "Hello World") ;; => #<procedure (?)>
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;; Use extra parens around function definition to execute
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((lambda () "Hello World")) ;; => Hello World ;; argument list is empty
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;; A function with an argument
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((lambda (x) (* x x)) 3) ;; => 9
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;; A function with two arguments
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((lambda (x y) (* x y)) 2 3) ;; => 6
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;; assign a function to a variable
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(define sqr (lambda (x) (* x x)))
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sqr ;; => #<procedure (sqr x)>
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(sqr 3) ;; => 9
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;; We can shorten this using the function definition syntactic sugar
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(define (sqr x) (* x x))
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(sqr 3) ;; => 9
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;; We can redefine existing procedures
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(foldl cons '() '(1 2 3 4 5)) ;; => (((((() . 1) . 2) . 3) . 4) . 5)
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(define (foldl func accu alist)
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(if (null? alist)
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accu
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(foldl func (func (car alist) accu) (cdr alist))))
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(foldl cons '() '(1 2 3 4 5)) ;; => (5 4 3 2 1)
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 5. Equality
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; For numbers use '='
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(= 3 3.0) ;; => #t
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(= 2 1) ;; => #f
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;; 'eq?' returns #t if two arguments refer to the same object in memory
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;; In other words, it's a simple pointer comparison.
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(eq? '() '()) ;; => #t ;; there's only one empty list in memory
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(eq? (list 3) (list 3)) ;; => #f ;; not the same object
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(eq? 'yes 'yes) ;; => #t
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(eq? 3 3) ;; => #t ;; don't do this even if it works in this case
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(eq? 3 3.0) ;; => #f ;; it's better to use '=' for number comparisons
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(eq? "Hello" "Hello") ;; => #f
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;; 'eqv?' is same as 'eq?' all datatypes except numbers and characters
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(eqv? 3 3.0) ;; => #f
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(eqv? (expt 2 3) (expt 2 3)) ;; => #t
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(eqv? 'yes 'yes) ;; => #t
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;; 'equal?' recursively compares the contents of pairs, vectors, and strings,
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;; applying eqv? on other objects such as numbers and symbols.
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;; A rule of thumb is that objects are generally equal? if they print the same.
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(equal? '(1 2 3) '(1 2 3)) ;; => #t
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(equal? #(a b c) #(a b c)) ;; => #t
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(equal? 'a 'a) ;; => #t
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(equal? "abc" "abc") ;; => #t
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;; In Summary:
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;; eq? tests if objects are identical
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;; eqv? tests if objects are operationally equivalent
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;; equal? tests if objects have same structure and contents
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;; Comparing strings for equality
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(string=? "Hello" "Hello") ;; => #t
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 6. Control Flow
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; Conditionals
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(if #t ;; test expression
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"True" ;; then expression
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"False") ;; else expression
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;; => "True"
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(if (> 3 2)
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"yes"
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"no") ;; => "yes"
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;; In conditionals, all values that are not '#f' are treated as true.
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;; 0, '(), #() "" , are all true values
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(if 0
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"0 is not false"
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"0 is false") ;; => "0 is not false"
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;; 'cond' chains a series of tests and returns as soon as it encounters a true condition
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;; 'cond' can be used to simulate 'if/elseif/else' statements
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(cond ((> 2 2) "not true so don't return this")
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((< 2 5) "true, so return this")
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(else "returning default")) ;; => "true, so return this"
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;; A case expression is evaluated as follows:
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;; The key is evaluated and compared with each datum in sense of 'eqv?',
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;; The corresponding clause in the matching datum is evaluated and returned as result
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(case (* 2 3) ;; the key is 6
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((2 3 5 7) 'prime) ;; datum 1
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((1 4 6 8) 'composite)) ;; datum 2; matched!
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;; => composite
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;; case with else clause
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(case (car '(c d))
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((a e i o u) 'vowel)
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((w y) 'semivowel)
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(else 'consonant)) ;; => consonant
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;; Boolean expressions
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;; 'and' returns the first expression that evaluates to #f
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;; otherwise, it returns the result of the last expression
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(and #t #f (= 2 2.0)) ;; => #f
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(and (< 2 5) (> 2 0) "0 < 2 < 5") ;; => "0 < 2 < 5"
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;; 'or' returns the first expression that evaluates to #t
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;; otherwise the result of the last expression is returned
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(or #f #t #f) ;; => #t
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(or #f #f #f) ;; => #f
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;; 'when' is like 'if' without the else expression
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(when (positive? 5) "I'm positive") ;; => "I'm positive"
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;; 'unless' is equivalent to (when (not <test>) <expr>)
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(unless (null? '(1 2 3)) "not null") ;; => "not null"
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;; Loops
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;; loops can be created with the help of tail-recursions
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(define (loop count)
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(unless (= count 0)
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(print "hello")
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(loop (sub1 count))))
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(loop 4) ;; => hello, hello ...
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;; Or with a named let
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(let loop ((i 0) (limit 5))
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(when (< i limit)
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(printf "i = ~a\n" i)
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(loop (add1 i) limit))) ;; => i = 0, i = 1....
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;; 'do' is another iteration construct
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;; It initializes a set of variables and updates them in each iteration
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;; A final expression is evaluated after the exit condition is met
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(do ((x 0 (add1 x ))) ;; initialize x = 0 and add 1 in each iteration
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((= x 10) (print "done")) ;; exit condition and final expression
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(print x)) ;; command to execute in each step
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;; => 0,1,2,3....9,done
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;; Iteration over lists
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(for-each (lambda (a) (print (* a a)))
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'(3 5 7)) ;; => 9, 25, 49
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;; 'map' is like for-each but returns a list
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(map add1 '(11 22 33)) ;; => (12 23 34)
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 7. Extensions
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; The CHICKEN core is very minimal, but additional features are provided by library extensions known as Eggs.
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;; You can install Eggs with 'chicken-install <eggname>' command.
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;; complex numbers
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3+4i ;; => 3+2i
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;; Supports fractions without falling back to inexact flonums
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1/3 ;; => 1/3
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;; provides support for large integers through bignums
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(expt 9 20) ;; => 12157665459056928801
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;; And other 'extended' functions
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(log 10 (exp 1)) ;; => 2.30258509299405
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(numerator 2/3) ;; => 2
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;; 'utf8' provides unicode support
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(import utf8)
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"\u03BBx:(\u03BC\u0251.\u0251\u2192\u0251).xx" ;; => "λx:(μɑ.ɑ→ɑ).xx"
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;; 'posix' provides file I/O and lots of other services for unix-like operating systems
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;; Some of the functions are not available in Windows system,
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;; See http://wiki.call-cc.org/man/5/Module%20(chicken%20file%20posix) for more details
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;; Open a file to append, open "write only" and create file if it does not exist
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(define outfn (file-open "chicken-hen.txt" (+ open/append open/wronly open/creat)))
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;; write some text to the file
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(file-write outfn "Did chicken came before hen?")
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;; close the file
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(file-close outfn)
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;; Open the file "read only"
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(define infn (file-open "chicken-hen.txt" open/rdonly))
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;; read some text from the file
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(file-read infn 30) ;; => ("Did chicken came before hen? ", 28)
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(file-close infn)
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;; CHICKEN also supports SRFI (Scheme Requests For Implementation) extensions
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;; See 'http://srfi.schemers.org/srfi-implementers.html" to see srfi's supported by CHICKEN
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(import srfi-1) ;; list library
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(filter odd? '(1 2 3 4 5 6 7)) ;; => (1 3 5 7)
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(count even? '(1 2 3 4 5)) ;; => 2
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(take '(12 24 36 48 60) 3) ;; => (12 24 36)
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(drop '(12 24 36 48 60) 2) ;; => (36 48 60)
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(circular-list 'z 'q) ;; => z q z q ...
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(import srfi-13) ;; string library
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(string-reverse "pan") ;; => "nap"
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(string-index "Turkey" #\k) ;; => 3
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(string-every char-upper-case? "CHICKEN") ;; => #t
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(string-join '("foo" "bar" "baz") ":") ;; => "foo:bar:baz"
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 8. Macros
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; A 'for .. in ..' iteration like python, for lists
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(define-syntax for
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(syntax-rules (in)
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((for elem in alist body ...)
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(for-each (lambda (elem) body ...) alist))))
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(for x in '(2 4 8 16)
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(print x)) ;; => 2, 4, 8, 16
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(for chr in (string->list "PENCHANT")
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(print chr)) ;; => P, E, N, C, H, A, N, T
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;; While loop
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(define-syntax while
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(syntax-rules ()
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((while cond body ...)
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(let loop ()
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(when cond
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body ...
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(loop))))))
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(let ((str "PENCHANT") (i 0))
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(while (< i (string-length str)) ;; while (condition)
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(print (string-ref str i)) ;; body
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(set! i (add1 i))))
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;; => P, E, N, C, H, A, N, T
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;; Advanced Syntax-Rules Primer -> http://petrofsky.org/src/primer.txt
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;; Macro system in chicken -> http://lists.gnu.org/archive/html/chicken-users/2008-04/msg00013.html
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; 9. Modules
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;; Also See http://wiki.call-cc.org/man/5/Modules
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;; The 'test' module exports a value named 'hello' and a macro named 'greet'
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(module test (hello greet)
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(import scheme)
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(define-syntax greet
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(syntax-rules ()
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((_ whom)
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(begin
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(display "Hello, ")
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(display whom)
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(display " !\n") ) ) ) )
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(define (hello)
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(greet "world") ) )
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;; we can define our modules in a separate file (say test.scm) and load them to the interpreter with
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;; (load "test.scm")
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;; import the module
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(import test)
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(hello) ;; => Hello, world !
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(greet "schemers") ;; => Hello, schemers !
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;; We can compile the module files in to shared libraries by using following command,
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;; csc -s test.scm
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;; (load "test.so")
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;; Functors
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;; Functors are high level modules that can be parameterized by other modules
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;; Following functor requires another module named 'M' that provides a function called 'multiply'
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;; The functor itself exports a generic function 'square'
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(functor (squaring-functor (M (multiply))) (square)
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(import scheme M)
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(define (square x) (multiply x x)))
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;; Module 'nums' can be passed as a parameter to 'squaring-functor'
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(module nums (multiply)
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(import scheme) ;; predefined modules
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(define (multiply x y) (* x y)))
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;; the final module can be imported and used in our program
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(module number-squarer = (squaring-functor nums))
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(import number-squarer)
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(square 3) ;; => 9
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;; We can instantiate the functor for other inputs
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;; Here's another example module that can be passed to squaring-functor
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(module stars (multiply)
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(import chicken scheme) ;; chicken module for the 'use' keyword
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(use srfi-1) ;; we can use external libraries in our module
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(define (multiply x y)
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(list-tabulate x (lambda _ (list-tabulate y (lambda _ '*))))))
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(module star-squarer = (squaring-functor stars))
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(import star-squarer)
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(square 3) ;; => ((* * *)(* * *)(* * *))
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```
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## Further Reading
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* [CHICKEN User's Manual](https://wiki.call-cc.org/manual).
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* [R5RS standards](http://www.schemers.org/Documents/Standards/R5RS)
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## Extra Info
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* [For programmers of other languages](https://wiki.call-cc.org/chicken-for-programmers-of-other-languages)
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* [Compare CHICKEN syntax with other languages](http://plr.sourceforge.net/cgi-bin/plr/launch.py)
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