427 lines
12 KiB
Scheme
427 lines
12 KiB
Scheme
; femtoLisp standard library
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; by Jeff Bezanson
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; Public Domain
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(set 'list (lambda args args))
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(set 'setq (macro (name val)
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(list set (list quote name) val)))
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(setq sp '| |)
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(setq nl '|
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|)
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; convert a sequence of body statements to a single expression.
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; this allows define, defun, defmacro, let, etc. to contain multiple
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; body expressions as in Common Lisp.
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(setq f-body (lambda (e)
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(cond ((atom e) e)
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((eq (cdr e) ()) (car e))
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(t (cons progn e)))))
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(setq defmacro
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(macro (name args . body)
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(list 'setq name (list 'macro args (f-body body)))))
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; support both CL defun and Scheme-style define
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(defmacro defun (name args . body)
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(list 'setq name (list 'lambda args (f-body body))))
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(defmacro define (name . body)
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(if (symbolp name)
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(list 'setq name (car body))
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(cons 'defun (cons (car name) (cons (cdr name) body)))))
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(defun identity (x) x)
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(setq null not)
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(defun consp (x) (not (atom x)))
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(defun map (f lst)
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(if (atom lst) lst
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(cons (f (car lst)) (map f (cdr lst)))))
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(defmacro let (binds . body)
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(cons (list 'lambda (map car binds) (f-body body))
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(map cadr binds)))
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(defun nconc lsts
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(cond ((null lsts) ())
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((null (cdr lsts)) (car lsts))
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(t ((lambda (l d) (if (null l) d
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(prog1 l
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(while (consp (cdr l)) (set 'l (cdr l)))
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(rplacd l d))))
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(car lsts) (apply nconc (cdr lsts))))))
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(defun append lsts
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(cond ((null lsts) ())
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((null (cdr lsts)) (car lsts))
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(t ((label append2 (lambda (l d)
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(if (null l) d
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(cons (car l)
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(append2 (cdr l) d)))))
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(car lsts) (apply append (cdr lsts))))))
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(defun member (item lst)
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(cond ((atom lst) ())
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((eq (car lst) item) lst)
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(t (member item (cdr lst)))))
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(defun macrop (e) (and (consp e) (eq (car e) 'macro) e))
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(defun macrocallp (e) (and (symbolp (car e))
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(boundp (car e))
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(macrop (eval (car e)))))
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(defun macroapply (m args) (apply (cons 'lambda (cdr m)) args))
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(defun macroexpand-1 (e)
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(if (atom e) e
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(let ((f (macrocallp e)))
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(if f (macroapply f (cdr e))
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e))))
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; convert to proper list, i.e. remove "dots", and append
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(defun append.2 (l tail)
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(cond ((null l) tail)
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((atom l) (cons l tail))
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(t (cons (car l) (append.2 (cdr l) tail)))))
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(defun macroexpand (e)
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((label mexpand
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(lambda (e env f)
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(progn
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(while (and (consp e)
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(not (member (car e) env))
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(set 'f (macrocallp e)))
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(set 'e (macroapply f (cdr e))))
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(if (and (consp e)
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(not (or (eq (car e) 'quote)
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(eq (car e) quote))))
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(let ((newenv
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(if (and (or (eq (car e) 'lambda) (eq (car e) 'macro))
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(consp (cdr e)))
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(append.2 (cadr e) env)
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env)))
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(map (lambda (x) (mexpand x newenv nil)) e))
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e))))
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e nil nil))
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; uncomment this to macroexpand functions at definition time.
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; makes typical code ~25% faster, but only works for defun expressions
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; at the top level.
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;(defmacro defun (name args . body)
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; (list 'setq name (list 'lambda args (macroexpand (f-body body)))))
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; same thing for macros. enabled by default because macros are usually
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; defined at the top level.
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(defmacro defmacro (name args . body)
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(list 'setq name (list 'macro args (macroexpand (f-body body)))))
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(setq = eq)
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(setq eql eq)
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(define (/= a b) (not (eq a b)))
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(define != /=)
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(define (> a b) (< b a))
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(define (<= a b) (not (< b a)))
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(define (>= a b) (not (< a b)))
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(define (mod x y) (- x (* (/ x y) y)))
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(define (abs x) (if (< x 0) (- x) x))
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(define (truncate x) x)
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(setq K prog1) ; K combinator ;)
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(define (funcall f . args) (apply f args))
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(define (symbol-function sym) (eval sym))
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(define (symbol-value sym) (eval sym))
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(define (caar x) (car (car x)))
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(define (cadr x) (car (cdr x)))
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(define (cdar x) (cdr (car x)))
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(define (cddr x) (cdr (cdr x)))
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(define (caaar x) (car (car (car x))))
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(define (caadr x) (car (car (cdr x))))
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(define (cadar x) (car (cdr (car x))))
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(define (caddr x) (car (cdr (cdr x))))
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(define (cdaar x) (cdr (car (car x))))
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(define (cdadr x) (cdr (car (cdr x))))
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(define (cddar x) (cdr (cdr (car x))))
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(define (cdddr x) (cdr (cdr (cdr x))))
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(define (equal a b)
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(if (and (consp a) (consp b))
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(and (equal (car a) (car b))
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(equal (cdr a) (cdr b)))
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(eq a b)))
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; compare imposes an ordering on all values. yields -1 for a<b,
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; 0 for a==b, and 1 for a>b. lists are compared up to the first
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; point of difference.
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(defun compare (a b)
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(cond ((eq a b) 0)
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((or (atom a) (atom b)) (if (< a b) -1 1))
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(t (let ((c (compare (car a) (car b))))
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(if (not (eq c 0))
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c
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(compare (cdr a) (cdr b)))))))
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(defun every (pred lst)
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(or (atom lst)
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(and (pred (car lst))
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(every pred (cdr lst)))))
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(defun any (pred lst)
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(and (consp lst)
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(or (pred (car lst))
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(any pred (cdr lst)))))
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(defun listp (a) (or (eq a ()) (consp a)))
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(defun length (l)
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(if (null l) 0
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(+ 1 (length (cdr l)))))
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(defun nthcdr (n lst)
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(if (<= n 0) lst
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(nthcdr (- n 1) (cdr lst))))
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(defun list-ref (lst n)
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(car (nthcdr n lst)))
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(defun list* l
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(if (atom (cdr l))
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(car l)
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(cons (car l) (apply list* (cdr l)))))
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(defun nlist* l
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(if (atom (cdr l))
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(car l)
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(rplacd l (apply nlist* (cdr l)))))
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(defun lastcdr (l)
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(if (atom l) l
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(lastcdr (cdr l))))
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(defun last (l)
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(cond ((atom l) l)
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((atom (cdr l)) l)
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(t (last (cdr l)))))
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(defun map! (f lst)
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(prog1 lst
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(while (consp lst)
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(rplaca lst (f (car lst)))
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(set 'lst (cdr lst)))))
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(defun mapcar (f . lsts)
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((label mapcar-
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(lambda (lsts)
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(cond ((null lsts) (f))
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((atom (car lsts)) (car lsts))
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(t (cons (apply f (map car lsts))
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(mapcar- (map cdr lsts)))))))
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lsts))
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(defun transpose (M) (apply mapcar (cons list M)))
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(defun filter (pred lst)
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(cond ((null lst) ())
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((not (pred (car lst))) (filter pred (cdr lst)))
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(t (cons (car lst) (filter pred (cdr lst))))))
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(define (foldr f zero lst)
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(if (null lst) zero
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(f (car lst) (foldr f zero (cdr lst)))))
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(define (foldl f zero lst)
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(if (null lst) zero
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(foldl f (f (car lst) zero) (cdr lst))))
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(define (reverse lst) (foldl cons nil lst))
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(define (reduce0 f zero lst)
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(if (null lst) zero
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(reduce0 f (f zero (car lst)) (cdr lst))))
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(defun reduce (f lst)
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(reduce0 f (car lst) (cdr lst)))
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(define (copy-list l) (map identity l))
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(define (copy-tree l)
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(if (atom l) l
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(cons (copy-tree (car l))
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(copy-tree (cdr l)))))
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(define (assoc item lst)
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(cond ((atom lst) ())
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((eq (caar lst) item) (car lst))
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(t (assoc item (cdr lst)))))
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(define (nreverse l)
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(let ((prev nil))
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(while (consp l)
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(set 'l (prog1 (cdr l)
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(rplacd l (prog1 prev
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(set 'prev l))))))
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prev))
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(defmacro let* (binds . body)
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(cons (list 'lambda (map car binds)
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(cons progn
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(nconc (map (lambda (b) (cons 'setq b)) binds)
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body)))
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(map (lambda (x) nil) binds)))
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(defmacro labels (binds . body)
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(cons (list 'lambda (map car binds)
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(cons progn
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(nconc (map (lambda (b)
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(list 'setq (car b) (cons 'lambda (cdr b))))
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binds)
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body)))
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(map (lambda (x) nil) binds)))
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(defmacro when (c . body) (list if c (f-body body) nil))
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(defmacro unless (c . body) (list if c nil (f-body body)))
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(defmacro dotimes (var . body)
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(let ((v (car var))
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(cnt (cadr var)))
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(list 'let (list (list v 0))
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(list while (list < v cnt)
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(list prog1 (f-body body) (list 'setq v (list + v 1)))))))
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(defun map-int (f n)
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(let ((acc nil))
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(dotimes (i n)
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(setq acc (cons (f i) acc)))
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(nreverse acc)))
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; property lists
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(setq *plists* nil)
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(defun symbol-plist (sym)
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(cdr (or (assoc sym *plists*) '(()))))
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(defun set-symbol-plist (sym lst)
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(let ((p (assoc sym *plists*)))
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(if (null p) ; sym has no plist yet
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(setq *plists* (cons (cons sym lst) *plists*))
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(rplacd p lst))))
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(defun get (sym prop)
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(let ((pl (symbol-plist sym)))
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(if pl
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(let ((pr (member prop pl)))
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(if pr (cadr pr) nil))
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nil)))
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(defun put (sym prop val)
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(let ((p (assoc sym *plists*)))
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(if (null p) ; sym has no plist yet
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(setq *plists* (cons (list sym prop val) *plists*))
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(let ((pr (member prop p)))
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(if (null pr) ; sym doesn't have this property yet
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(rplacd p (cons prop (cons val (cdr p))))
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(rplaca (cdr pr) val)))))
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val)
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; setf
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; expands (setf (place x ...) v) to (mutator (f x ...) v)
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; (mutator (identity x ...) v) is interpreted as (mutator x ... v)
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(setq *setf-place-list*
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; place mutator f
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'((car rplaca identity)
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(cdr rplacd identity)
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(caar rplaca car)
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(cadr rplaca cdr)
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(cdar rplacd car)
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(cddr rplacd cdr)
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(caaar rplaca caar)
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(caadr rplaca cadr)
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(cadar rplaca cdar)
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(caddr rplaca cddr)
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(cdaar rplacd caar)
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(cdadr rplacd cadr)
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(cddar rplacd cdar)
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(cdddr rplacd cddr)
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(get put identity)
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(aref aset identity)
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(symbol-function set identity)
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(symbol-value set identity)
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(symbol-plist set-symbol-plist identity)))
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(defun setf-place-mutator (place val)
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(if (symbolp place)
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(list 'setq place val)
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(let ((mutator (assoc (car place) *setf-place-list*)))
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(if (null mutator)
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(error '|setf: error: unknown place | (car place))
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(if (eq (caddr mutator) 'identity)
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(cons (cadr mutator) (append (cdr place) (list val)))
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(list (cadr mutator)
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(cons (caddr mutator) (cdr place))
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val))))))
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(defmacro setf args
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(f-body
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((label setf-
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(lambda (args)
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(if (null args)
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nil
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(cons (setf-place-mutator (car args) (cadr args))
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(setf- (cddr args))))))
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args)))
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(defun revappend (l1 l2) (nconc (reverse l1) l2))
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(defun nreconc (l1 l2) (nconc (nreverse l1) l2))
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(defun builtinp (x)
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(and (atom x)
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(not (symbolp x))
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(not (numberp x))))
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(defun self-evaluating-p (x)
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(or (eq x nil)
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(eq x t)
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(and (atom x)
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(not (symbolp x)))))
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; backquote
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(defmacro backquote (x) (bq-process x))
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(defun splice-form-p (x)
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(or (and (consp x) (or (eq (car x) '*comma-at*)
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(eq (car x) '*comma-dot*)))
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(eq x '*comma*)))
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(defun bq-process (x)
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(cond ((self-evaluating-p x) x)
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((atom x) (list quote x))
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((eq (car x) 'backquote) (bq-process (bq-process (cadr x))))
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((eq (car x) '*comma*) (cadr x))
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((not (any splice-form-p x))
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(let ((lc (lastcdr x))
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(forms (map bq-bracket1 x)))
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(if (null lc)
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(cons 'list forms)
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(nconc (cons 'nlist* forms) (list (bq-process lc))))))
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(t (let ((p x) (q '()))
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(while (and (consp p)
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(not (eq (car p) '*comma*)))
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(setq q (cons (bq-bracket (car p)) q))
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(setq p (cdr p)))
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(cons 'nconc
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(cond ((consp p) (nreconc q (list (cadr p))))
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((null p) (nreverse q))
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(t (nreconc q (list (bq-process p))))))))))
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(defun bq-bracket (x)
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(cond ((atom x) (list cons (bq-process x) nil))
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((eq (car x) '*comma*) (list cons (cadr x) nil))
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((eq (car x) '*comma-at*) (list 'copy-list (cadr x)))
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((eq (car x) '*comma-dot*) (cadr x))
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(t (list cons (bq-process x) nil))))
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; bracket without splicing
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(defun bq-bracket1 (x)
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(if (and (consp x) (eq (car x) '*comma*))
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(cadr x)
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(bq-process x)))
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