;; some useful (or at least amusing) functions and macros

(provide 'stuff.scm)

(when (provided? 'pure-s7)
  (define (let->list e) (reverse! (map values e))))


;;; ----------------
(define empty?
  (let ((+documentation+ "(empty? obj) returns #t if obj is an empty sequence"))
    (lambda (obj)
      (and (not (pair? obj))
	   (if (hash-table? obj)
	       (zero? (hash-table-entries obj)) ; length here is table size
	       (eqv? (length obj) 0))))))

(define applicable? arity)

(define (nth-value n . args) ; untested...
  (and (> (length args) n)
       (list-ref args n)))

(define indexable?
  (let ((+documentation+ "(indexable? obj) returns #t if obj can be applied to an index: (obj 0)"))
    (lambda (obj)
      (and (sequence? obj)
	   (applicable? obj)))))

(define (ow!)
  (call-with-output-string
   (lambda (p)
     (let ((ow (owlet))
	   (elist (list (rootlet))))

       ;; show current error data
       (format p "error: ~A" (ow 'error-type))
       (let ((info (ow 'error-data)))
	 (if (and (pair? info)
		  (string? (car info)))
	     (format p ": ~A" (catch #t
				(lambda ()
				  (apply format #f info))
				(lambda args
				  "<error in format>")))
	     (if (not (null? info))
		 (format p ": ~A" info))))

       (format p "~%error-code: ~S" (ow 'error-code))
       (when (ow 'error-line)
	 (format p "~%error-file/line: ~A[~A]" (ow 'error-file) (ow 'error-line)))

       ;; show history, if available
       (when (pair? (ow 'error-history)) ; a circular list, starts at error-code, entries stored backwards
	 (let ((history ())
	       (lines ())
	       (files ())
	       (start (ow 'error-history)))
	   (do ((x (cdr start) (cdr x))
		(i 0 (+ i 1)))
	       ((or (eq? x start)
		    (= i (*s7* 'history-size)))
		(format p "~%error-history:~%    ~S" (car start))
		(do ((expr history (cdr expr))
		     (line lines (cdr line))
		     (f files (cdr f)))
		    ((null? expr))
		  (if (and (integer? (car line))
			   (string? (car f))
			   (not (string=? (car f) "*stdout*")))
		      (format p "~%    ~A~40T;~A[~A]" (object->string (car expr) #t 60) (car f) (car line))
		      (if (not (null? (car expr)))
			  (format p "~%    ~A" (object->string (car expr) #t 60)))))
		(format p "~%"))
	     (set! history (cons (car x) history))
	     (set! lines (cons (and (pair? (car x)) (pair-line-number (car x))) lines))
	     (set! files (cons (and (pair? (car x)) (pair-filename (car x))) files)))))

       (let-temporarily (((*s7* 'print-length) 8))
	 (do ((e (outlet ow) (outlet e)))
	     ((memq e elist))
	   (if (and (number? (length e)) ; with-let + mock-data + length method?
		    (> (length e) 0))
	       (format p "~%~{~A~| ~}~%" e)
	       (format p "e: ~S~%" e))
	   (set! elist (cons e elist))))))))

#|
(set! (hook-functions *error-hook*)
      (list (lambda (hook)
	      (apply format *stderr* (hook 'data))
	      (newline *stderr*)
	      (when ((owlet) 'error-line)
		(format *stderr* "~S line ~A~%" ((owlet) 'error-file) ((owlet) 'error-line)))
	      (do ((e (outlet (owlet)) (outlet e)))
		  ((eq? e (rootlet)))
		(format *stderr* "~{  ~A~%~}~%" e))
	      (format *stderr* "~%~A~%" (stacktrace)))))
|#

;;; ----------------
(define-macro (typed-let vals . body) ; vals: ((var init [type])...)...) as in (typed-let ((i 0 integer?))...)
  `(let ,(map (lambda (val)
		 (list (car val) (cadr val)))
	       vals)
     ,@(map (lambda (val)
	      (if (pair? (cddr val))
		  (let ((init-args (if (pair? (caddr val)) ; setter: (lambda (s v [e]) ...)
				       (if (eqv? (length (cadr (caddr val))) 3)
					   (list (list 'quote (car val)) (car val) (list 'curlet))
					   (list (list 'quote (car val)) (car val)))
				       (list (car val))))) ; setter: integer? etc
		    `(begin
		       (unless (,(caddr val) ,@init-args) ; check initial value (already set)
			 (error 'wrong-type "typed-let: '~S initial value ~S is not ~S" ',(car val) ,(car val) ,(caddr val)))
		       (set! (setter ',(car val)) ,(caddr val))))
		  (values)))
	    vals)
     ,@body))

(define-macro (typed-inlet . vals) ; vals: ((var init [type])...)...) as in (typed-inlet (i 0 integer?)...)
  (let ((e (gensym)))
    `(let ((,e (typed-let ,vals (curlet))))
       (set! (outlet ,e) (rootlet)) ; mimic (inlet ...)
       ,e)))

(define-macro (typed-lambda args . body) ; (typed-lambda ((var [type])...) ...), (typed-lambda ((i integer?) (x real?) z) (+ i x z))
  (if (symbol? args)
      (apply lambda args body)
      (let ((new-args (copy args)))
	(do ((p new-args (cdr p)))
	    ((not (pair? p)))
	  (if (pair? (car p))
	      (set-car! p (caar p))))
	`(lambda ,new-args
	   ,@(map (lambda (arg)
		    (if (pair? arg)
			`(unless (,(cadr arg) ,(car arg))
			   (error 'wrong-type-arg "~S is not ~S~%" ',(car arg) ',(cadr arg)))
			(values)))
		  args)
	   ,@body))))

;;; ----------------

(define (n-values n . args) ; called pick-values in fennel
  (let ((len (length args)))
    (if (<= len n) ; maybe issue a warning in this case: "not enough values"? and n==0 will return #<unspecified>
	(apply values args)
	(apply values (copy args (make-list n))))))

;(display (+ 4 (n-values 2 (values 1 2 3)))) (newline)
;(display (let () (define (f) (values 1 2 3)) (+ 4 (n-values 2 (f))))) (newline)
;(display (let () (define (f) (values 1 2 3)) (+ 4 (n-values 1 (f))))) (newline)
;(display (let () (define (f) (values 1 2 3)) (+ 4 (n-values 3 (f))))) (newline)
;(display (let () (define (f) (values 1 2 3)) (+ 4 (n-values 12 (f))))) (newline)
;(display (let () (define (f) 3) (+ 4 (n-values 12 (f))))) (newline)

(define-macro (prog1 first . body)
  (let ((result (gensym)))
    `(let ((,result (list ,first)))
       ,@body
       (if (null? (cdr ,result))
	   (car ,result)
	   (apply values ,result)))))


;;; ----------------
(define (first obj)  (if (sequence? obj) (obj 0) (error 'wrong-type-arg "first argument, ~S, is not a sequence" obj)))
(define (second obj) (if (sequence? obj) (obj 1) (error 'wrong-type-arg "second argument, ~S, is not a sequence" obj)))
(define (third obj)  (if (sequence? obj) (obj 2) (error 'wrong-type-arg "third argument, ~S, is not a sequence" obj)))
(define (fourth obj) (if (sequence? obj) (obj 3) (error 'wrong-type-arg "fourth argument, ~S, is not a sequence" obj)))
(define (fifth obj)  (if (sequence? obj) (obj 4) (error 'wrong-type-arg "fifth argument, ~S, is not a sequence" obj)))
(define (sixth obj)  (if (sequence? obj) (obj 5) (error 'wrong-type-arg "sixth argument, ~S, is not a sequence" obj)))
(define (seventh obj)(if (sequence? obj) (obj 6) (error 'wrong-type-arg "seventh argument, ~S, is not a sequence" obj)))
(define (eighth obj) (if (sequence? obj) (obj 7) (error 'wrong-type-arg "eighthment, ~S, is not a sequence" obj)))
(define (ninth obj)  (if (sequence? obj) (obj 8) (error 'wrong-type-arg "ninth argument, ~S, is not a sequence" obj)))
(define (tenth obj)  (if (sequence? obj) (obj 9) (error 'wrong-type-arg "tenth argument, ~S, is not a sequence" obj)))

(define (built-in? x)
  (not (undefined? (eval-string (string-append "#_" (object->string x)))))) ; just a guess...

#|
(define (the type expr)
  (if (type expr)
      expr
      (error 'bad-type "~S is ~S but should be ~S" expr (type-of expr) type)))
|#
(define (the type expr)
  (let ((e expr)
	(bp type))
    (if (and (procedure? bp)
	     (signature bp)
	     (eq? 'boolean? (car (signature bp))))
	(let ((result (if (= (car (arity bp)) 1)
			  (type e)
			  (bp 'the e))))
	  (if result e (error 'bad-type "~S is ~S but should be ~S in (the ~S ~S)" e (type-of e) bp type expr)))
	(error 'bad-type "~S is not a boolean procedure, (the ~S ~S)" bp type expr))))

(define iota
  (let ((+documentation+ "(iota n (start 0) (incr 1)) returns a list counting from start for n:\n\
    (iota 3) -> '(0 1 2)"))
    (lambda* (n (start 0) (incr 1))
      (if (or (not (integer? n))
	      (< n 0))
	  (error 'wrong-type-arg "iota length ~A should be a non-negative integer" n))
      (let ((lst (make-list n)))
	(do ((p lst (cdr p))
	     (i start (+ i incr)))
	    ((null? p) lst)
	  (set! (car p) i))))))

;(define cdr* list-tail)

(define make-circular-list
  (let ((+documentation+ "(make-circular-list n init) returns a circular list with n entries initialized to init:\n\
    (make-circular-list 3 #f) -> #1=(#f #f #f . #1#)"))
    (lambda* (n init)
      (let ((lst (make-list n init)))
	(set-cdr! (list-tail lst (- n 1)) lst)))))

(define circular-list
  (let ((+documentation+ "(circular-list . objs) returns a circular list with objs:\n\
    (circular-list 1 2) -> #1=(1 2 . #1#)"))
    (lambda objs
      (let ((lst (copy objs)))
	(set-cdr! (list-tail lst (- (length lst) 1)) lst)))))

(define circular-list?
  (let ((+documentation+ "(circular-list? obj) returns #t if obj is a circular list"))
    (lambda (obj)
      (catch #t
	(lambda () (infinite? (length obj)))
	(lambda args #f)))))

(define linearize
  (let ((+documentation+ "(linearize lst) turns a circular list into normal list:\n\
    (linearize (circular-list 1 2)) -> '(1 2)"))
    (lambda (lst)
      (let lin-1 ((lst lst)
                  (result ())
                  (sofar ()))
        (if (or (not (pair? lst)) (memq lst sofar))
            (reverse! result)
            (lin-1 (cdr lst) (cons (car lst) result) (cons lst sofar)))))))

(define cyclic?
  (let ((+documentation+ "(cyclic obj) returns #t if the sequence obj contains any cycles"))
    (lambda (obj)
      (pair? (cyclic-sequences obj)))))

(define copy-tree
  (let ((+documentation+ "(copy-tree lst) returns a full copy of lst"))
    (lambda (lis)
      (if (pair? lis)
	  (copy lis :readable)
	  lis))))

(define tree-member tree-memq)

(define adjoin
  (let ((+documentation+ "(adjoin obj lst) adds obj to lst if it is not already in lst, returning the new list"))
    (lambda (obj lst)
      (if (member obj lst) lst (cons obj lst)))))

(define (cdr-assoc obj lst)
  (cond ((assoc obj lst) => cdr)
	(else #f)))


;;; this used to be built into s7.c, but no one uses it.
(define-macro (multiple-value-set! vars expr . body)
  (if (pair? vars)
      (let ((local-vars (map (lambda (n) (gensym)) vars)))
	`((lambda ,local-vars
	    ,@(map (lambda (n ln) `(set! ,n ,ln)) vars local-vars)
	    ,@body)
	  ,expr))
      (if (and (null? vars) (null? expr))
	  (cons 'begin body)
	  (error 'syntax-error "multiple-value-set! vars/exprs messed up"))))



;;; ----------------
(define-macro (fully-macroexpand form)
  (list 'quote
        (let expand ((form form))
          (cond ((not (pair? form)) form)
                ((and (symbol? (car form))
                      (macro? (symbol->value (car form))))
                 (expand (apply macroexpand (list form))))
                ((and (eq? (car form) 'set!)
                      (pair? (cdr form))
                      (pair? (cadr form))
                      (macro? (symbol->value (caadr form))))
                 (expand
                  (apply macroexpand
                         (list (cons (setter (symbol->value (caadr form)))
                               (append (cdadr form) (copy (cddr form))))))))
                (else (cons (expand (car form)) (expand (cdr form))))))))

(define-macro (define-with-macros name&args . body)
  `(apply define ',name&args (list (fully-macroexpand `(begin ,,@body)))))

(define setf
  (let ((args (gensym))
	(name (gensym)))
    (apply define-bacro `((,name . ,args)
			  (unless (null? ,args)
			    (apply set! (car ,args) (cadr ,args) ())
			    (apply setf (cddr ,args)))))))


(define-macro* (incf sym (inc 1))
  `(set! ,sym (+ ,sym ,inc))) ; or (list-values set! sym (list-values + sym inc))

;; (define-bacro* (incf-1 sym (inc 1)) (apply set! sym (list + sym inc) ()))

(define-macro* (decf sym (dec 1))
  `(set! ,sym (- ,sym ,dec)))

(define-macro (shiftf . places)
  (let ((tmp (gensym)))
    `(let ((,tmp ,(car places)))
       ,@(map (lambda (a b)
		`(set! ,a ,b))
	      places
	      (cdr places))
       ,tmp)))

(define-macro (rotatef . places)
  (let ((tmp (gensym))
	(last (places (- (length places) 1))))
    `(let ((,tmp ,(car places)))
       ,@(map (lambda (a b)
		`(set! ,a ,b))
	      places
	      (cdr places))
       (set! ,last ,tmp))))

#|
(define (rotate! lst)
  (if (and (pair? lst)
	   (pair? (cdr lst)))
      (let ((lr (reverse! lst)))
	(cons (car lr) (reverse! (cdr lr))))
      lst))
|#

(define swap! (letrec ((no-pairs? (lambda (lst) ; see s7test.scm for swap! examples
				   (or (null? lst)
				       (and (not (pair? (car lst)))
					    (no-pairs? (cdr lst)))))))
	        (macro (a b)
		  (cond ((not (or (symbol? a) (pair? a)))
			 (error 'wrong-type-arg "can't (swap! ~A ~A): ~A is not a symbol or a pair" a b a))
			
			((not (or (symbol? b) (pair? b)))
			 (error 'wrong-type-arg "can't (swap! ~A ~A): ~A is not a symbol or a pair" a b b))

			((and (symbol? a) (immutable? a))
			 (error 'wrong-type-args "can't (swap! ~A ~A): ~A is immutable" a b a))
			
			((and (symbol? b) (immutable? b))
			 (error 'wrong-type-args "can't (swap! ~A ~A): ~A is immutable" a b b))
			
			((and (or (symbol? a) (hash-table? a) (let? a) (no-pairs? (cdr a)))
			      (or (symbol? b) (hash-table? b) (let? b) (no-pairs? (cdr b))))
			 ;; we assume above hash-tables and lets don't use expressions for the key/variable names
			 (let ((tmp (gensym "swap!-")))
			   `(let ((,tmp ,a))
			      (set! ,a ,b)
			      (set! ,b ,tmp))))
			
			(else     ; here either a or b or both are pairs with exprs as "indices"
			 (let ((a-object (if (pair? a) (car a) a))
			       (b-object (if (pair? b) (car b) b))
			       (a-indices (and (pair? a) (cdr a)))
			       (b-indices (and (pair? b) (cdr b)))
			       (tmp-a-indices (gensym "swap!-"))
			       (tmp-b-indices (gensym "swap!-"))
			       (tmp (gensym "swap!-")))
			   `(let ((,tmp-a-indices (and (pair? ',a) (map eval ',a-indices))) ; eval once-only in run-time env
				  (,tmp-b-indices (and (pair? ',b) (map eval ',b-indices))))
			      (let ((,tmp (if (pair? ',a) 
					      (apply ,a-object ,tmp-a-indices)
					      ,a)))
				(if (pair? ',a)
				    (if (not (pair? ',b))
					(set! (,a-object (apply values ,tmp-a-indices)) ,b)
					(set! (,a-object (apply values ,tmp-a-indices)) (apply ,b-object ,tmp-b-indices)))
				    (set! ,a (apply ,b-object ,tmp-b-indices)))
				(if (not (pair? ',b))
				    (if (pair? ',a)
					(set! ,b ,tmp))
				    (set! (,b-object (apply values ,tmp-b-indices)) ,tmp))))))))))

(define-macro (progv vars vals . body)
  `(apply (apply lambda ,vars ',body) ,vals))

(define-macro (symbol-set! var val) ; like CL's set
  `(apply set! ,var ',val ()))

(define-macro (value->symbol expr)
  `(let ((val ,expr)
	 (e1 (curlet)))
     (call-with-exit
      (lambda (return)
	(do ((e e1 (outlet e))) ()
	  (for-each
	   (lambda (slot)
	     (if (equal? val (cdr slot))
		 (return (car slot))))
	   e)
	  (if (eq? e (rootlet))
	      (return #f)))))))

(define-macro (enum . args)
  `(for-each define ',args (iota (length ',args))))

(define-macro (destructuring-bind lst expr . body) ; if only there were some use for this!
  (cons 'let
	(cons (let flatten ((lst1 lst)
			    (lst2 (eval expr))
			    (args ()))
		(cond ((null? lst1) args)
		      ((not (pair? lst1)) (cons (list lst1 lst2) args))
		      (else (flatten (car lst1) (car lst2)
				     (flatten (cdr lst1) (cdr lst2) args)))))
	      body)))

#|
;; kinda ugly!
(define-macro (and-map func args)
  `(let and-map-loop ((args ,args))
     (or (null? args)
	 (and (eval (list ,func (car args)))
	      (and-map-loop (cdr args))))))
|#

(define-macro (and-let* vars . body)      ; bind vars, if any is #f stop, else evaluate body with those bindings
  (if (list? vars)
      `(let () (and ,@(map (lambda (v) (cons 'define v)) vars) (begin ,@body)))
      (error 'wrong-type-arg "and-let* var list is ~S" vars)))

(define-macro (let*-temporarily vars . body)
  `(with-let (#_inlet :orig (#_curlet)
		      :saved (#_list ,@(map car vars)))
     (dynamic-wind
	 (lambda () #f)
	 (lambda ()
	   (with-let orig
	     ,@(map (lambda (v)
		      `(set! ,(car v) ,(cadr v)))
		    vars)
	     ,@body))
	 (lambda ()
	   ,@(map (let ((ctr -1))
		    (lambda (v)
		      (if (symbol? (car v))
			  `(set! (orig ',(car v)) (list-ref saved ,(set! ctr (+ ctr 1))))
			  `(set! (with-let orig ,(car v)) (list-ref saved ,(set! ctr (+ ctr 1)))))))
		  vars)))))

(define-macro (let/setter vars . body)
  (let ((setters (map (lambda (binding)
			 (and (pair? (cddr binding))
			      (caddr binding)))
		       vars))
	(gsetters (gensym)))
    `(let ((,gsetters (list ,@setters))
	   ,@(map (lambda (binding)
		    (list (car binding) (cadr binding)))
		  vars))
       ,@(do ((s setters (cdr s))
	      (var vars (cdr var))
	      (i 0 (+ i 1))
	      (result ()))
	     ((null? s)
	      (reverse result))
	   (if (car s)
	       (set! result (cons `(set! (setter (quote ,(caar var))) (list-ref ,gsetters ,i)) result))))
       ,@body)))

(define-macro (while test . body)      ; while loop with predefined break and continue
  (let ((loop (gensym)))
    `(call-with-exit
      (lambda (break)
	(let ,loop ()
	  (call-with-exit
	   (lambda (continue)
	     (do ()
		 ((not ,test) (break))
	       ,@body)))
	  (,loop))))))

(define-macro (anaphoric-when test . body) ; use "test-result" as the variable holding the test result
  `(let ((test-result ,test))
     (when test-result ,@body)))

(define-macro (do* spec end . body)
  `(let* ,(map (lambda (var)
		 (list (car var) (cadr var)))
	       spec)
     (do () ,end
       ,@body
       ,@(map (lambda (var)
		(if (pair? (cddr var))
		    `(set! ,(car var) ,(caddr var))
		    (values)))
	      spec))))

(define-macro (string-case selector . clauses)
  (cons 'case       ; case with string constant keys
	(cons (list 'symbol selector)
	      (map (lambda (clause)
		     (if (pair? (car clause))
			 (cons (map symbol (car clause)) (cdr clause))
			 clause))
		   clauses))))

(define-macro (eval-case key . clauses) ; case with evaluated key-lists
  (let ((select (gensym)))
    `(let ((,select ,key))
       (cond ,@(map (lambda (lst)
		      (if (not (pair? (car lst)))
			  lst
			  (cons `(member ,select (list ,@(car lst)))
				(cdr lst))))
		    clauses)))))



;;; ----------------
(define hash-table->alist
  (let ((+documentation+ "(hash-table->alist table) returns the contents of table as an association list:\n\
    (hash-table->alist (hash-table '(a . 1))) -> '((a . 1))"))
    (lambda (table)
      (if (hash-table? table)
	  (map values table)
	  (error 'wrong-type-arg "hash-table->alist argument, ~A, is not a hash-table" table)))))

(define merge-hash-tables append)


;;; ----------------
(define-macro (c?r path)
  (define (X-marks-the-spot accessor tree)
    (if (pair? tree)
	(or (X-marks-the-spot (cons 'car accessor) (car tree))
	    (X-marks-the-spot (cons 'cdr accessor) (cdr tree)))
	(and (eq? tree 'X) accessor)))
  (let ((body 'lst))
    (for-each
     (lambda (f)
       (set! body (list f body)))
     (reverse (X-marks-the-spot () path)))
    `(dilambda
      (lambda (lst)
	,body)
      (lambda (lst val)
	(set! ,body val)))))



;;; ----------------
(define find-if
  (let ((+documentation+ "(find-if func sequence) applies func to each member of sequence.\n\
If func approves of one, find-if returns that member of the sequence"))
    (lambda (f sequence)
      (call-with-exit
       (lambda (return)
	 (for-each (lambda (arg)
		     (if (f arg)
			 (return arg)))
		   sequence)
	 #f)))))

(define member?
  (let ((+documentation+ "(member? obj sequence) returns #t if obj is an element of sequence"))
    (lambda (obj sequence)
      (find-if (lambda (x) (equal? x obj)) sequence))))


(define index-if
  (let ((+documentation+ "(index-if func sequence) applies func to each member of sequence.\n\
If func approves of one, index-if returns the index that gives that element's position.\n\
    (index-if (lambda (x) (= x 32)) #(0 1 32 4)) -> 2\n\
    (index-if (lambda (x) (= (cdr x) 32)) (hash-table '(a . 1) '(b . 32))) -> 'b"))
    (lambda (f sequence)
      (call-with-exit
       (lambda (return)
	 (if (or (hash-table? sequence)
		 (let? sequence))
	     (for-each (lambda (arg)
			 (if (f arg) (return (car arg))))
		       sequence)
	     (let ((position 0))
	       (for-each (lambda (arg)
			   (if (f arg) (return position))
			   (set! position (+ position 1)))
			 sequence)))
	 #f)))))

(define count-if
  (let ((+documentation+ "(count-if func sequence) applies func to each member of sequence, returning the number of times func approves."))
    (lambda (f sequence)
      (let ((count 0))
	(for-each (lambda (arg)
		    (if (f arg)
			(set! count (+ count 1))))
		  sequence)
	count))))

(define every?
  (let ((+documentation+ "(every? func sequence) returns #t if func approves of every member of sequence"))
    (lambda (f sequence)
      (call-with-exit
       (lambda (return)
	 (for-each (lambda (arg) (if (not (f arg)) (return #f))) sequence)
	 #t)))))

(define any?
  (let ((+documentation+ "(any? func sequence) returns #t if func approves of any member of sequence"))
    (lambda (f sequence)
      (call-with-exit
       (lambda (return)
	 (for-each (lambda (arg) (if (f arg) (return #t))) sequence)
	 #f)))))

(define collect-if
  (let ((+documentation+ "(collect-if type func sequence) gathers the elements of sequence that satisfy func, and returns them via type:\n\
    (collect-if list integer? #(1.4 2/3 1 1+i 2)) -> '(1 2)"))
    (lambda (type f sequence)
      (unless (sequence? sequence)
	(error 'wrong-type-arg "collect-if: sequence arg is ~A" sequence))
      (if (eq? type hash-table)
	  (apply hash-table (map (lambda (arg) (if (f arg) (values (car arg) (cdr arg)) (values))) sequence))
	  (apply type (map (lambda (arg) (if (f arg) arg (values))) sequence))))))

;;; if type=list, this is slightly wasteful because list currently copies its args, so:
;;;   ((if (eq? type list) values (values apply type)) ...) would work
;;;
;;; to return (f arg) rather than arg, (apply type (map f sequence))

(define remove-if
  (let ((+documentation+ "(remove-if type f sequence) returns via type the elements of sequence that do not satisfy func:\n\
    (remove-if list integer? #(1.4 2/3 1 1+i 2)) -> '(1.4 2/3 1+1i)"))
    (lambda (type f sequence)
      (unless (sequence? sequence)
	(error 'wrong-type-arg "remove-if: sequence arg is ~A" sequence))
      (collect-if type (lambda (obj) (not (f obj))) sequence))))

(define nonce
  (let ((+documentation+ "(nonce type sequence) returns via type the elements of sequence that occur only once"))
    (lambda (type sequence)
      (collect-if type (lambda (obj) (= (count-if (lambda (x) (equal? x obj)) sequence) 1)) sequence))))


(define full-find-if
  (let ((+documentation+ "(full-find-if func sequence) searches sequence, and recursively any sequences it contains, for an element that satisfies func"))
    (lambda (f sequence)
      (if (and (procedure? f)
	       (aritable? f 1))
	  (if (sequence? sequence)
	      (call-with-exit
	       (lambda (return)
		 (let full-find-if-1 ((seq sequence))
		   (for-each
		    (lambda (x)
		      (if (f x)
			  (return x)
			  (if (sequence? x) (full-find-if-1 x))))
		    seq))
		 #f))
	      (error 'wrong-type-arg "full-find-if second argument, ~A, is not a sequence" sequence))
	  (error 'wrong-type-arg "full-find-if first argument, ~A, is not a procedure of one argument" f)))))

(define full-count-if
  (let ((+documentation+ "(full-count-if func sequence) searches sequence, and recursively any sequences it contains, returning the number of elements that satisfy func"))
    (lambda (f sequence)
      (let ((count 0))
	(full-find-if (lambda (x) (if (f x) (set! count (+ count 1))) #f) sequence)
	count))))

(define full-index-if
  (let ((+documentation+ "(full-index-if func sequence) searches sequence, and recursively any sequences it contains, returning the indices of the first element that satisfies func:\n\
    (full-index-if (lambda (x) (and (integer? x) (= x 3))) '(1 (2 3))) -> '(1 1)"))
    (lambda (f sequence)
      (call-with-exit
       (lambda (return)
	 (letrec ((full-index-if-1
		   (lambda (f seq path)
		     (if (or (hash-table? seq)
			     (let? seq))
			 (for-each (lambda (arg)
				     (if (f arg)
					 (return (reverse (cons (car arg) path)))
					 (if (indexable? (cdr arg))
					     (full-index-if-1 f (cdr arg) (cons (car arg) path)))))
				   seq)
			 (let ((position 0))
			   (for-each (lambda (arg)
				       (if (f arg)
					   (return (reverse (cons position path)))
					   (if (indexable? arg)
					       (full-index-if-1 f arg (cons position path))))
				       (set! position (+ position 1)))
				     seq))))))
	   (full-index-if-1 f sequence ())
	   #f))))))


(define (make-complete-iterator obj)
  (let ((iters ())
	(cycles (cyclic-sequences obj))
	(seen-cycles ()))

    (define (make-careful-iterator p)
      (if (not (pair? p))
	  (make-iterator p)
	  (let ((len (length p)))
	    (make-iterator
	     (cond ((infinite? len)      ; circular list
		    (let ((cur p)
			  (+iterator+ #t))
		      (lambda ()
			(if (memq cur seen-cycles)
			    (*s7* 'iterator-at-end-value)
			    (let ((result (car cur)))
			      (if (memq cur cycles)
				  (set! seen-cycles (cons cur seen-cycles)))
			      (set! cur (cdr cur))
			      result)))))
		   ((positive? len)      ; normal list
		    p)
		   (else
		    (let ((cur p)        ; dotted list
			  (+iterator+ #t))
		      (lambda ()
			(if (pair? cur)
			    (let ((result (car cur)))
			      (set! cur (cdr cur))
			      result)
			    (let ((result cur))
			      (set! cur (*s7* 'iterator-at-end-value))
			      result))))))))))

    (make-iterator
     (let ((iter (make-careful-iterator obj))
	   (+iterator+ #t))
       (define (iterloop) ; define returns the new value
	 (define (iter-memq p q)
	   (and (pair? q)
		(or (eq? p (iterator-sequence (car q)))
		    (iter-memq p (cdr q)))))
	 (let ((result (iter)))
	   (cond ((length result)
		  (if (or (memq result seen-cycles)             ; we've dealt with it already, so skip it
			  (eq? result (iterator-sequence iter))
			  (iter-memq result iters))             ; we're dealing with it the right now
		      (iterloop)                                ; this means the outermost sequence is ignored if encountered during the traversal
		      (begin
			(set! iters (cons iter iters))
			(set! iter (make-careful-iterator result))
			result)))

		 ((not (eq? result (*s7* 'iterator-at-end-value)))
		  result)

		 ((null? iters)
		  (*s7* 'iterator-at-end-value))

		 (else
		  (set! seen-cycles (cons (iterator-sequence iter) seen-cycles))
		  (set! iter (car iters))
		  (set! iters (cdr iters))
		  (iterloop)))))))))


(define safe-find-if
  (let ((+documentation+ "(safe-find-if func sequence) searches sequence, and recursively any sequences it contains, for an element that satisfies func.\
Unlike full-find-if, safe-find-if can handle any circularity in the sequences."))
    (lambda (f sequence)
      (let ((iter (make-complete-iterator sequence)))
	(let loop ((x (iter)))
	  (if (f x) x
	      (and (not (and (eq? x (*s7* 'iterator-at-end-value))
			     (iterator-at-end? iter)))
		   (loop (iter)))))))))

(define (safe-count-if f sequence)
  ;; currently the complete-iterator above skips repetitions, including the outer sequence,
  ;;   so this count will be off if there are repeated cycles?
  ;; Perhaps make an iterator that returns everything.
  (if (sequence? sequence)
      (if (procedure? f)
	  (let ((count 0))
	    (safe-find-if (lambda (x) (if (f x) (set! count (+ count 1))) #f) sequence)
	    count)
	  (error 'wrong-type-arg "safe-count-if first argument, ~A, should be a function" f))
      (error 'wrong-type-arg "safe-count-if second argument, ~A, should be a sequence" sequence)))


;;; ----------------
(define sequences->list
  (let ((+documentation+ "(sequences->list . sequences) returns a list of elements of all the sequences:\n\
    (sequences->list \"hi\" #(0 1) (hash-table 'a 2)) -> '(#\\h #\\i 0 1 (a . 2))"))
    (lambda sequences
      (apply append
	     (map (lambda (sequence)
		    (map values sequence))
		  sequences)))))

(define concatenate
  (let ((+documentation+ "(concatenate type . sequences) concatenates sequences returning an object of type:\n\
    (concatenate vector '(1 2) #(3 4)) -> #(1 2 3 4)"))
    (lambda (type . sequences)
      (apply type (apply sequences->list sequences)))))

(define intersection
  (let ((+documentation+ "(intersection type . sequences) returns via type the intersection of the sequences:\n\
    (intersection vector '(1 2 3) #(2 3 4)) -> #(2 3)"))
    (lambda (type . sequences)
      (if (every? sequence? sequences)
	  (apply type (let ((lst ()))
			(if (pair? sequences)
			    (for-each (lambda (obj)
					(if (every? (lambda (seq)
						      (member? obj seq))
						    (cdr sequences))
					    (set! lst (cons obj lst))))
				      (car sequences)))
			(reverse lst)))
	  (error 'wrong-type-arg "intersection arguments should be sequences: ~A" sequences)))))

(define union
  (let ((+documentation+ "(union type . sequences) returns via type the union of the sequences:\n\
    (union vector '(1 2 3) #(2 3 4)) -> #(1 2 3 4)"))
    (lambda (type . sequences)
      (apply type (let ((lst ()))
		    (for-each (lambda (obj)
				(if (not (member obj lst))
				    (set! lst (cons obj lst))))
			      (apply sequences->list sequences))
		    (if (eq? type hash-table)
			(map (lambda (x) (values (car x) (cdr x))) (reverse lst))
			(reverse lst)))))))

(define asymmetric-difference
  (let ((+documentation+ "(asymmetric-difference type . sequences) returns the elements in the rest of the sequences that are not in the first:\n\
    (asymmetric-difference vector '(1 2 3) #(2 3 4) '(1 5)) -> #(4 5)"))
    (lambda (type . sequences) ; complement, elements in B's not in A
      (if (not (and (pair? sequences)
		    (pair? (cdr sequences))))
	  (type)
	  (collect-if type (lambda (obj)
			     (not (member obj (car sequences))))
		      (apply union list (cdr sequences)))))))

(define cl-set-difference
  (let ((+documentation+ "(cl-set-difference type . sequences) returns the elements in the first sequence that are not in the rest of the sequences:\n\
    (cl-set-difference vector '(1 2 3) #(2 3 4) '(1 5)) -> #()"))
    (lambda (type . sequences)     ; CL: elements in A not in B's
      (if (not (and (pair? sequences)
		    (pair? (cdr sequences))))
	  (type)
	  (let ((others (apply union list (cdr sequences))))
	    (collect-if type (lambda (obj)
			       (not (member obj others)))
			(car sequences)))))))

(define symmetric-difference
  (let ((+documentation+ "(symmetric-difference type . sequences) returns the elements that are in an odd number of the sequences:\n\
    (symmetric-difference vector '(1 2 3) #(2 3 4) '(5)) -> #(1 4 5)"))
    (lambda (type . sequences)  ; xor, elements in an odd number of sequences (logxor A B...)
      (let ((all (apply sequences->list sequences)))
	(collect-if type (lambda (obj)
			   (odd? (count-if (lambda (x)
					     (equal? x obj))
					   all)))
		    (apply union list sequences))))))

(define power-set
  (let ((+documentation+ "(power-set type . sequences) returns the power set of the union of the elements in the sequences."))
    (lambda (type . sequences) ; ignoring repeats
      (apply type
	     (let pset ((set (apply union list sequences)))
	       (if (null? set)
		   '(())
		   (let ((rest (pset (cdr set))))
		     (append rest (map (lambda (subset) (cons (car set) subset)) rest)))))))))

;;; ----------------
;;;   now superseded by built-in type-of
(define ->predicate
  (let ((predicates (list integer? rational? real? complex? number?
			  byte-vector? string?
			  float-vector? int-vector? vector?
			  null? proper-list? pair? list?
			  keyword? gensym? symbol?
			  char? string?
			  hash-table?
			  iterator?
			  continuation?
			  input-port? output-port?
			  let?
			  dilambda? procedure? macro?
			  boolean?
			  random-state?
			  eof-object?
			  c-object?
			  c-pointer?
			  (lambda (obj)
			    (eq? obj #<unspecified>))
			  (lambda (obj)
			     (eq? obj #<undefined>))
			  (lambda (obj)
			    (memq obj (list quote if when unless begin set! let let* letrec letrec* cond and or case do
					    lambda lambda* define define* define-macro define-macro* define-bacro define-bacro*
					    define-constant with-baffle macroexpand with-let)))))
	(+documentation+ "(->predicate obj) returns the type predicate function for obj: (->predicate 31) -> integer?"))
    (lambda (obj)
      (find-if (lambda (pred) (pred obj)) predicates))))

(define add-predicate
  (let ((+documentation+ "(add-predicate p) adds p (a boolean function of one argument) to the list of predicates used by ->predicate"))
    (lambda (p)
      (if (and (procedure? p)
	       (aritable? p 1))
	  (let ((e (funclet ->predicate)))
	    (set! (e 'predicates) (cons p (e 'predicates))))
	  (error 'wrong-type-arg "add-predicate argument, ~A, is not a procedure of one argument" p)))))

(define typeq?
  (let ((+documentation+ "(typeq? . objs) returns #t if all objs have the same type (as determined by ->predicate)"))
    (lambda objs
      (or (null? objs)
	  (every? (->predicate (car objs)) (cdr objs))))))

(define-macro (typecase expr . clauses) ; actually type=any boolean func
  (let ((obj (gensym)))
    `(begin                             ; normally this would be (let ((,obj ,expr)) ...)
       (define ,obj ,expr)              ;   but use begin so that internal defines are not blocked
       (cond ,@(map (lambda (clause)
		      (if (memq (car clause) '(#t else))
			  clause
			  (cons (if (= (length (car clause)) 1)
				    (list (caar clause) obj)
				    (cons 'or (map (lambda (type)
						     (list type obj))
						   (car clause))))
				(cdr clause))))
		    clauses)))))



;;; ----------------
(define 2^n?
  (let ((+documentation+ "(2^n? x) returns #t if x is a power of 2"))
    (lambda (x)
      (and (integer? x)
	   (not (zero? x))
	   (zero? (logand x (- x 1)))))))

(define (2^n-1? x)
  (and (integer? x)
       (zero? (logand x (+ x 1)))))

(define (2-ruler n) ; translated from CLOCC cllib/math.lisp, ruler
  ;; The exponent of the largest power of 2 which divides the given number.
  (- (integer-length (logand n (- n))) 1))

(define (lognand . ints)  ; viewed as (not (and ...))
  (lognot (apply logand ints)))

(define (lognor . ints)
  (lognot (apply logior ints)))

(define (logeqv . ints)
  (lognot (apply logxor (if (odd? (length ints))
			    (values -1 ints) ; Clisp does it this way
			    ints))))

(define (log-none-of . ints)  ; bits on in none of ints
  (lognot (apply logior ints)))

(define log-all-of logand)    ; bits on in all of ints
(define log-any-of logior)    ; bits on in at least 1 of ints

(define (log-n-of n . ints)   ; return the bits on in exactly n of ints
  (cond ((not (integer? n))
	 (error 'wrong-type-arg "log-n-of first argument, ~A, should be an integer" n))
	((not (every? integer? ints))
	 (error 'wrong-type-arg "log-n-of ints arguments, ~A, should all be integers" ints))
	((negative? n)
	 (error 'out-of-range "log-n-of first argument should be positive: ~A" n))
	(else
	 (let ((len (length ints)))
	   (cond ((= len 0) (if (= n 0) -1 0))
		 ((= n 0)   (lognot (apply logior ints)))
		 ((= n len) (apply logand ints))
		 ((> n len) 0)
		 (#t
		  (do ((1s 0)
		       (prev ints)
		       (nxt (cdr ints))
		       (ln (- len 1))
		       (nn (- n 1))
		       (i 0 (+ i 1)))
		      ((= i len) 1s)
		    (let ((cur (ints i)))
		      (if (= i 0)
			  (set! 1s (logior 1s (logand cur (apply log-n-of nn nxt))))
			  (let ((mid (cdr prev)))
			    (set! (cdr prev) (if (= i ln) () (cdr mid)))
			    (set! 1s (logior 1s (logand cur (apply log-n-of nn ints))))
			    (set! (cdr prev) mid)
			    (set! prev mid)))))))))))

;; from Rick
(define (byte siz pos) ;; -> cache size, position and mask.
  (list siz pos (ash (- (ash 1 siz) 1) pos)))

(define (ldb bytespec integer)
  (ash (logand integer (caddr bytespec))
       (- (cadr bytespec))))

(define (dpb integer bytespec into)
  (logior (ash (logand integer (- (ash 1 (car bytespec)) 1)) (cadr bytespec))
	  (logand into (lognot (caddr bytespec)))))


;;; ----------------
(define-macro* (define-class class-name inherited-classes (slots ()) (methods ()))
  `(let ((outer-env (outlet (curlet)))
	 (new-methods ())
	 (new-slots ()))

     (for-each
      (lambda (class)
	;; each class is a set of nested environments, the innermost (first in the list)
	;;   holds the local slots which are copied each time an instance is created,
	;;   the next holds the class slots (global to all instances, not copied);
	;;   these hold the class name and other such info.  The remaining environments
	;;   hold the methods, with the localmost method first.  So in this loop, we
	;;   are gathering the local slots and all the methods of the inherited
	;;   classes, and will splice them together below as a new class.

	(set! new-slots (append (let->list class) new-slots))
	(do ((e (outlet (outlet class)) (outlet e)))
	    ((or (not (let? e))
		 (eq? e (rootlet))))
	  (set! new-methods (append (let->list e) new-methods))))
      ,inherited-classes)

     (let ((remove-duplicates
	    (lambda (lst)         ; if multiple local slots with same name, take the localmost
	      (letrec ((rem-dup
			(lambda (lst nlst)
			  (cond ((null? lst) nlst)
				((assq (caar lst) nlst) (rem-dup (cdr lst) nlst))
				(else (rem-dup (cdr lst) (cons (car lst) nlst)))))))
		(reverse (rem-dup lst ()))))))
       (set! new-slots
	     (remove-duplicates
	      (append (map (lambda (slot)
			     (if (pair? slot)
				 (cons (car slot) (cadr slot))
				 (cons slot #f)))
			   ,slots)                    ; the incoming new slots, #f is the default value
		      new-slots)))                    ; the inherited slots

       (set! new-methods
	     (remove-duplicates
	      (append (map (lambda (method)
			     (if (pair? method)
				 (cons (car method) (cadr method))
				 (cons method #f)))
			   ,methods)                     ; the incoming new methods

		      ;; add an object->string method for this class (this is already a generic function).
		      (list (cons 'object->string
				  (lambda (obj . rest)
				    (if (and (pair? rest)
					     (eq? (car rest) :readable))    ; write readably
					(format #f "(make-~A~{ :~A ~W~^~})"
						',class-name
						(map (lambda (slot)
						       (values (car slot) (cdr slot)))
						     obj))
					(format #f "#<~A: ~{~A~^ ~}>"
						',class-name
						(map (lambda (slot)
						       (list (car slot) (cdr slot)))
						     obj))))))
		      (reverse! new-methods)))))                  ; the inherited methods, shadowed automatically

     (let ((new-class (openlet
                       (apply sublet                             ; the local slots
			      (sublet                            ; the global slots
				  (apply inlet                   ; the methods
					 new-methods)
				'class-name ',class-name         ; class-name slot
				'inherited ,inherited-classes
				'inheritors ())                  ; classes that inherit from this class
			      new-slots))))

       (varlet outer-env
	 ',class-name new-class                                  ; define the class as class-name in the calling environment

	 ;; define class-name? type check
	 (symbol (symbol->string ',class-name) "?")
	 (lambda (obj)
	   (and (let? obj)
		(eq? (obj 'class-name) ',class-name))))

       (varlet outer-env
	 ;; define the make-instance function for this class.
	 ;;   Each slot is a keyword argument to the make function.
	 (symbol "make-" (symbol->string ',class-name))
	 (apply lambda* (map (lambda (slot)
			       (if (pair? slot)
				   (list (car slot) (cdr slot))
				   (list slot #f)))
			     new-slots)
		`((let ((new-obj (copy ,,class-name)))
		    ,@(map (lambda (slot)
			     `(set! (new-obj ',(car slot)) ,(car slot)))
			   new-slots)
		    new-obj))))

       ;; save inheritance info for this class for subsequent define-method
       (letrec ((add-inheritor (lambda (class)
				 (for-each add-inheritor (class 'inherited))
				 (if (not (memq new-class (class 'inheritors)))
				     (set! (class 'inheritors) (cons new-class (class 'inheritors)))))))
	 (for-each add-inheritor ,inherited-classes))

       ',class-name)))

(define-macro (define-generic name)    ; (define (genfun any) ((any 'genfun) any))
  `(define ,name
     (lambda args
       (let ((gf ((car args) ',name))) ; get local definition
	 (if (not (eq? gf ,name))      ; avoid infinite recursion
             (apply gf args)
	     (error 'syntax-error "attempt to call generic function wrapper recursively"))))))

(define-macro (define-slot-accessor name slot)
  `(define ,name (dilambda
		  (lambda (obj) (obj ',slot))
		  (lambda (obj val) (set! (obj ',slot) val)))))

(define-macro (define-method name-and-args . body)
  `(let* ((outer-env (outlet (curlet)))
	  (method-name (car ',name-and-args))
	  (method-args (cdr ',name-and-args))
	  (object (caar method-args))
	  (class (symbol->value (cadar method-args)))
	  (old-method (class method-name))
	  (method (apply lambda* method-args ',body)))

     ;; define the method as a normal-looking function
     ;;   s7test.scm has define-method-with-next-method that implements call-next-method here
     ;;   it also has make-instance
     (varlet outer-env
       method-name (apply lambda* method-args
			  `(((,object ',method-name)
			     ,@(map (lambda (arg)
				      (if (pair? arg) (car arg) arg))
				    method-args)))))

     ;; add the method to the class
     (varlet (outlet (outlet class)) method-name method)

     ;; if there are inheritors, add it to them as well, but not if they have a shadowing version
     (for-each
      (lambda (inheritor)
	(if (not (eq? (inheritor method-name) #<undefined>)) ; defined? goes to the global env
	    (if (eq? (inheritor method-name) old-method)
		(set! (inheritor method-name) method))
	    (varlet (outlet (outlet inheritor)) method-name method)))
      (class 'inheritors))

     method-name))

(define (all-methods obj method)
  ;; for arbitrary method combinations: this returns a list of all the methods of a given name
  ;;   in obj's class and the classes it inherits from (see example below)
  (if (symbol? method)
      (let ((methods (let ((base-method (obj method)))
		       (if (procedure? base-method) (list base-method) ()))))
	(for-each
	 (lambda (ancestor)
	   (let ((next-method (ancestor method)))
	     (if (and (procedure? next-method)
		      (not (memq next-method methods)))
		 (set! methods (cons next-method methods)))))
	 (obj 'inherited))
	(reverse methods))
      (error 'wrong-type-arg "all-methods 'method argument should be a symbol: ~A" method)))



;;; ----------------
(define for-each-subset
  (let ((+documentation+ "(for-each-subset func args) forms each subset of args, then applies func to the subsets that fit its arity"))
    (lambda (func args)
      (let subset ((source args)
                   (dest ())
                   (len 0))
        (if (null? source)
            (if (aritable? func len)
                (apply func dest))
            (begin
              (subset (cdr source) (cons (car source) dest) (+ len 1))
              (subset (cdr source) dest len)))))))

(define for-each-permutation
  (let ((+documentation+ "(for-each-permutation func vals) applies func to every permutation of vals:\n\
    (for-each-permutation (lambda args (format () \"~{~A~^ ~}~%\" args)) '(1 2 3))"))
    (lambda (func vals)
      (define (pinner cur nvals len)
	(if (= len 1)
	    (apply func (car nvals) cur)
	    (do ((i 0 (+ i 1))                       ; I suppose a named let would be more Schemish
		 (start nvals nvals))
		((= i len))
	      (set! nvals (cdr nvals))
	      (let ((cur1 (cons (car nvals) cur)))  ; add (car nvals) to our arg list
		(set! (cdr start) (cdr nvals))      ; splice out that element and
		(pinner cur1 (cdr start) (- len 1)) ;   pass a smaller circle on down, "wheels within wheels"
		(set! (cdr start) nvals)))))        ; restore original circle
      (let ((len (length vals)))
	(set-cdr! (list-tail vals (- len 1)) vals)    ; make vals into a circle
	(pinner () vals len)
	(set-cdr! (list-tail vals (- len 1)) ())))))    ; restore its original shape



;;; ----------------
(define (clamp minimum x maximum) ; if min>max maybe an error? (clamp 3 2 1) -> 1
  (min maximum (max x minimum)))

(define (1- x) (- x 1))
(define (1+ x) (+ x 1))

(define n-choose-k
  (let ((+documentation+ "(n-choose-k n k) returns the binomial coefficient C(N,K)"))
    (lambda (n k)
      (if (not (integer? n))
	  (error 'wrong-type-arg "n-choose-k 'n argument, ~A, should be an integer" n)
	  (if (not (integer? k))
	      (error 'wrong-type-arg "n-choose-k 'k argument, ~A, should be an integer" k)
	      (let ((mn (min k (- n k))))
		(if (or (negative? mn)
			(negative? n))
		    0
		    (if (= mn 0)
			1
			(let ((mx (max k (- n k))))
			  (do ((cnk (+ 1 mx))
			       (i 2 (+ i 1)))
			      ((> i mn) cnk)
			    (set! cnk (/ (* cnk (+ mx i)) i))))))))))))

;;; ----------------

(define continuable-error
  (let ((+documentation+ "(continuable-error . args) is (apply error args) wrapped in a continuation named 'continue."))
    (lambda args
      (call/cc
       (lambda (continue)
	 (apply error args))))))

(define continue-from-error ; maybe arg for value to pass back
  (let ((+documentation+ "(continue-from-error) tries to continue from the point of the earlier continuable-error"))
    (lambda ()
      (if (continuation? ((owlet) 'continue))
	  (((owlet) 'continue))))))

;;; ----------------

(define (call-with-input-vector v proc)
  (if (vector? v)
      (let ((i -1))
	(proc (openlet
	       (inlet 'read (lambda (p)
			      (v (set! i (+ i 1))))))))
      (error 'wrong-type-arg "call-with-input-vector first argument, ~A, should be a vector" v)))

(define (call-with-output-vector proc)
  (let ((size 1)
	(i 0))
    (let* ((v (make-vector size #f))
	   (write-to-vector (lambda (obj p)
			      (when (= i size) ; make the vector bigger to accommodate the output
				(set! v (copy v (make-vector (set! size (* size 2)) #f))))
			      (set! (v i) obj)
			      (set! i (+ i 1))
			      #<unspecified>))) ; that's what write/display return!
      (proc (openlet
	     (inlet 'write (lambda* (obj p)
			     ((if (not (let? p)) write write-to-vector) obj p))
		    'display (lambda* (obj p)
			       ((if (not (let? p)) display write-to-vector) obj p))
		    'format (lambda (p . args)
			      (if (not (let? p))
				  (apply format p args)
				  (write (apply format #f args) p))))))
      (subvector v 0 i)))) ; ignore extra trailing elements (i = subvector length)



;;; ----------------

(define* (flatten-let e (n -1))
  (if (not (let? e))
      (error 'wrong-type-arg "flatten-let argument, ~A, is not a let" e)
      (do ((slots ())
	   (pe e (outlet pe))
	   (i 0 (+ i 1)))
	  ((or (eq? pe (rootlet))
	       (= i n))
	   (apply inlet slots))
	(for-each (lambda (slot)
		    (if (not (or (assq (car slot) slots)
				 (immutable? (car slot)))) ; immutable symbol
			(set! slots (cons slot slots))))
		  pe))))

(define* (owlets (ows 1)) (flatten-let (owlet) ows))



;;; ----------------

(define-macro (reflective-let vars . body)
  `(let ,vars
     ,@(map (lambda (vr)
	      `(set! (setter ',(car vr))
		     (lambda (s v)
		       (format *stderr* "~S -> ~S~%" s v)
		       v)))
	    vars)
     ,@body))

#|
(define-bacro (reflective-probe)
  (with-let (inlet 'e (outlet (curlet)))
    (for-each (lambda (var)
		(format *stderr* "~S: ~S~%" (car var) (cdr var)))
	      e)))
|#
;; ideally this would simply vanish, and make no change in the run-time state, but (values) here returns #<unspecified>
;;   (let ((a 1) (b 2)) (list (set! a 3) (reflective-probe) b)) -> '(3 2) not '(3 #<unspecified> 2)
;; perhaps if we want it to disappear:

(define-bacro (reflective-probe . body)
  (with-let (inlet :e (outlet (curlet))
		   :body body)
    (for-each (lambda (var)
		(format *stderr* "~S: ~S~%" (car var) (cdr var)))
	      e)
    (cons 'begin body)))

;; now (let ((a 1) (b 2)) (list (set! a 3) (reflective-probe b))) -> '(3 2)
;; and (let ((a 1) (b 2)) (list (set! a 3) (reflective-probe) b)) -> '(3 () 2)
;; or use it to print function args: (define (f a b) (reflective-probe) (+ a b))


#|
;; this tests a bacro for independence of any runtime names
;; (bacro-shaker reactive-set! '(let ((a 21) (b 1)) (reactive-set! a (* b 2)) (set! b 3) a))

(define (bacro-shaker bac example)

  (define (swap-symbols old-code syms)
    (if (null? old-code)
	()
	(if (symbol? old-code)
	    (let ((x (assq old-code syms)))
	      (if x
		  (cdr x)
		  (copy old-code)))
	    (if (pair? old-code)
		(cons (swap-symbols (car old-code) syms)
		      (swap-symbols (cdr old-code) syms))
		(copy old-code)))))

  (let ((e (outlet (curlet)))
	(source (cddr (cadr (caddr (procedure-source bac))))))
    (let ((symbols (gather-symbols source (rootlet) () ()))
	  (exsyms (gather-symbols (cadr example) (rootlet) () ())))
      ;; now try each symbol at each position in exsyms, in all combinations

      (let ((syms ()))
	(for-each
	 (lambda (s)
	   (set! syms (cons (cons s s) syms)))
	 exsyms)
	(let ((result (eval example e)))

	  (define (g . new-args)
	    (for-each (lambda (a b)
			(set-cdr! a b))
		      syms new-args)
	    (let ((code (swap-symbols example syms)))
	      (let ((new-result (catch #t
				  (lambda ()
				    (eval code e))
				  (lambda args
				    args))))
		(if (not (equal? result new-result))
		    (format *stderr* "~A -> ~A~%~A -> ~A~%"
			    example result
			    code new-result)))))

	  (define (f . args)
	    (for-each-permutation g args))

	  (let ((subsets ())
		(func f)
		(num-args (length exsyms))
		(args symbols))
	    (define (subset source dest len)
	      (if (null? source)
		  (begin
		    (set! subsets (cons dest subsets))
		    (if (= len num-args)
			(apply func dest)))
		  (begin
		    (subset (cdr source) (cons (car source) dest) (+ len 1))
		    (subset (cdr source) dest len))))
	    (subset args () 0)))))))
|#

;;; ----------------

(define* (subsequence obj (start 0) end)
  (let ((new-len (let ((len (length obj)))
		   (- (min len (or end len)) start))))
    (if (negative? new-len)
	(error 'out-of-range "end: ~A should be greater than start: ~A" (+ start new-len) start))

    (cond ((vector? obj)
	   (subvector obj start (+ start new-len)))

          ((string? obj)
           (if (integer? end)
               (substring obj start end)
               (substring obj start)))

          ((not (pair? obj))
           (if (defined? 'value obj #t)
	       (subsequence (obj 'value) start end)
	       (if (defined? 'subsequence obj #t)
		   ((obj 'subsequence) obj start end)
		   #f)))

          ((not end)
	   (list-tail obj start))

          (else
           (do ((lst (make-list new-len #f))
		(i 0 (+ i 1)))
	       ((= i new-len) lst)
	     (set! (lst i) (obj (+ i start))))))))

;;; ----------------

(define-macro (elambda args . body)  ; lambda but pass extra arg "*env*" = run-time env
  `(define-bacro (,(gensym) ,@args)
     `((lambda* ,(append ',args `((*env* (curlet))))
	 ,'(begin ,@body))
       ,,@args)))

(define-macro* (rlambda args . body) ; lambda* but eval arg defaults in run-time env
  (let ((arg-names (map (lambda (arg) (if (pair? arg) (car arg) arg)) args))
	(arg-defaults (map (lambda (arg) (if (pair? arg) (list (car arg) (list 'eval (cadr arg))) arg)) args)))
    `(define-bacro* (,(gensym) ,@arg-defaults)
       `((lambda ,',arg-names ,'(begin ,@body)) ,,@arg-names))))


;;; ----------------

(unless (or (defined? 'apropos)
	    (provided? 'snd))
  (define* (apropos name (port *stdout*) (e (rootlet)))
    (let ((ap-name (if (string? name)
		       name
		       (if (symbol? name)
			   (symbol->string name)
			   (error 'wrong-type-arg "apropos argument 1 should be a string or a symbol"))))
	  (ap-env (if (let? e)
		      e
		      (error 'wrong-type-arg "apropos argument 3 should be an environment")))
	  (ap-port (if (output-port? port)
		       port
		       (error 'wrong-type-arg "apropos argument 2 should be an output port"))))
      (for-each
       (lambda (binding)
	 (if (and (pair? binding)
		  (string-position ap-name (symbol->string (car binding))))
	     (format ap-port "~A: ~A~%"
		     (car binding)
		     (if (procedure? (cdr binding))
			 (documentation (cdr binding))
			 (cdr binding)))))
       ap-env))))

#|
(define* (apropos->list name (e (rootlet)))
  (let ((ap-name (if (string? name)
		     name
		     (if (symbol? name)
			 (symbol->string name)
			 (error 'wrong-type-arg "apropos->let argument 1 should be a string or a symbol")))))
    (map (lambda (binding)
	   (if (and (pair? binding)
		    (string-position ap-name (symbol->string (car binding))))
	       (if (procedure? (cdr binding))
		   (cons (car binding) (documentation (cdr binding)))
		   binding)
	       (values)))
	 (if (let? e)
	     e
	     (error 'wrong-type-arg "apropos argument 2 should be an environment")))))
|#


;;; --------------------------------------------------------------------------------

(define (*s7*->list) ; (let->list *s7*) flattened and using keywords
  (do ((p (let->list *s7*) (cdr p))
       (L ()))
      ((null? p)
       (reverse L))
    (set! L (cons (cdar p)
		  (cons (symbol->keyword (caar p))
			L)))))

(define (*s7*-reset)
  ;; commented-out fields are not settable
  (set! (*s7* 'accept-all-keyword-arguments) #f)
  (set! (*s7* 'autoloading?) #t)
  (set! (*s7* 'bignum-precision) 128)
  ;;(set! (*s7* 'catches) ())
  ;;(set! (*s7* 'cpu-time) 0.0)
  ;;(set! (*s7* 'c-types) ())
  (set! (*s7* 'debug) 0)
  (set! (*s7* 'default-hash-table-length) 8)
  (set! (*s7* 'default-random-state) (random-state 10426464598700316 1675393560))
  (set! (*s7* 'default-rationalize-error) 1e-12)
  (set! (*s7* 'equivalent-float-epsilon) 1e-15)
  (set! (*s7* 'expansions?) #t)
  ;;(set! (*s7* 'filenames) ("*stdout*" "*stderr*" "*stdin*"))
  ;;(set! (*s7* 'file-names) ("*stdout*" "*stderr*" "*stdin*"))
  (set! (*s7* 'float-format-precision) 16)
  ;;(set! (*s7* 'free-heap-size) 0)
  ;;(set! (*s7* 'gc-freed) 0)
  (set! (*s7* 'gc-info) (list 0 0 1000000000))
  ;;(set! (*s7* 'gc-protected-objects) #f)
  (set! (*s7* 'gc-resize-heap-by-4-fraction) 0.67)
  (set! (*s7* 'gc-resize-heap-fraction) 0.8)
  (set! (*s7* 'gc-stats) 0)
  (set! (*s7* 'gc-temps-size) 256)
  ;;(set! (*s7* 'gc-total-freed) 0)
  (set! (*s7* 'hash-table-float-epsilon) 1e-12)
  (set! (*s7* 'hash-table-missing-key-value) #f)
  (set! (*s7* 'heap-size) 64000)
  (set! (*s7* 'history) ())
  (set! (*s7* 'history-enabled) #f)
  (set! (*s7* 'history-size) 8)
  (set! (*s7* 'initial-string-port-length) 128)
  (set! (*s7* 'iterator-at-end-value) #<eof>)
  ;;(set! (*s7* 'major-version) 11)
  (set! (*s7* 'max-heap-size) 35184372088832)
  (set! (*s7* 'max-list-length) 1073741824)
  (set! (*s7* 'max-stack-size) 1073741824)
  (set! (*s7* 'max-string-length) 1073741824)
  (set! (*s7* 'max-string-port-length) 35184372088832)
  (set! (*s7* 'max-vector-dimensions) 512)
  (set! (*s7* 'max-vector-length) 4294967296)
  ;;(*s7* 'memory-usage)
  ;;(set! (*s7* 'minor-version) 5)
  ;;(set! (*s7* 'most-negative-fixnum) -9223372036854775808)
  ;;(set! (*s7* 'most-positive-fixnum) 9223372036854775807)
  (set! (*s7* 'muffle-warnings?) #f)
  (set! (*s7* 'number-separator) #\null)
  (set! (*s7* 'openlets) #t)
  (set! (*s7* 'output-file-port-length) 2048)
  (set! (*s7* 'print-length) 40)
  (set! (*s7* 'profile) 0)
  (set! (*s7* 'profile-info) #f)
  (set! (*s7* 'profile-prefix) #f)
  ;;(set! (*s7* 'rootlet-size) 580)
  (set! (*s7* 'safety) 0)
  ;;(set! (*s7* 'stack) #f)
  (set! (*s7* 'stacktrace-defaults) (list 30 45 80 45 #f))
  ;;(set! (*s7* 'stack-size) 4096)
  ;;(set! (*s7* 'stack-top) 15)
  (set! (*s7* 'symbol-quote?) #f)
  (set! (*s7* 'symbol-printer) #f)
  (set! (*s7* 'undefined-constant-warnings) #f)
  (set! (*s7* 'undefined-identifier-warnings) #f)
  ;;(set! (*s7* 'version) "s7 11.5, 12-June-2025")
  )

;;; --------------------------------------------------------------------------------

(define* (make-directory-iterator name (recursive #t))
  (if (not (string? name))
      (error 'wrong-type-arg "directory name should be a string: ~S" name)
      (make-iterator
       (with-let (sublet *libc* :name name :recursive recursive :NULL (c-pointer 0 'void*))
	 (let ((dir (opendir name)))
	   (if (equal? dir NULL)
	       (error 'io-error "can't open ~S: ~S" name (strerror (errno)))
	       (let ((+iterator+ #t))
		 (define reader
		   (let ((dirs ())
			 (dir-names ())
			 (dir-name name))
		     (lambda* (quit)                                ; returned from with-let
		       (if (eq? quit (*s7* 'iterator-at-end-value)) ; caller requests cleanup and early exit
			   (begin                                   ;   via ((iterator-sequence iter) (*s7* 'iterator-at-end-value))
			     (closedir dir)
			     (for-each closedir dirs)
			     (set! dirs ())
			     quit)
			   (let ((file (read_dir dir)))
			     (if (zero? (length file)) ; null filename => all done
				 (begin
				   (closedir dir)
				   (if (null? dirs)
				       (*s7* 'iterator-at-end-value)
				       (begin          ; else pop back to outer dir
					 (set! dir (car dirs))
					 (set! dirs (cdr dirs))
					 (set! dir-name (car dir-names))
					 (set! dir-names (cdr dir-names))
					 (reader))))
				 (if (member file '("." "..") string=?)
				     (reader)
				     (let ((full-dir-name (string-append dir-name "/" file)))
				       (if (and recursive
						(reader-cond
						 ((defined? 'directory?)
						  (directory? full-dir-name))
						 (#t (let* ((buf (stat.make))
							    (result (and (stat full-dir-name buf)
									 (S_ISDIR (stat.st_mode buf)))))
						       (free buf)
						       result))))
					   (let ((new-dir (opendir full-dir-name)))
					     (if (equal? new-dir NULL)  ; inner directory is unreadable?
						 (format *stderr* "can't read ~S: ~S" file (strerror (errno)))
						 (begin
						   (set! dirs (cons dir dirs))
						   (set! dir new-dir)
						   (set! dir-names (cons dir-name dir-names))
						   (set! dir-name full-dir-name)))
					     (reader))
					   (string-append dir-name "/" file)))))))))))))))))


;;; --------------------------------------------------------------------------------

(define (probe-eval val)
  (let ((probe-let (inlet)))
    (for-each
     (lambda (sym)
       (let ((func (symbol->value sym (rootlet))))
	 (if (and (procedure? func)
		  (not (immutable? sym))) ; apply-values etc
	     (varlet probe-let sym
		     (lambda args
		       (let-temporarily (((*s7* 'openlets) #f))
			 (let ((clean-args (map (lambda (arg)
						  (if (eq? arg probe-let)
						      (probe-let 'value)
						      arg))
						args)))
			   (format *stderr* "(~S ~{~S~^ ~})~%" sym clean-args)
			   (apply func clean-args))))))))
     (symbol-table))
    (varlet probe-let 'value val)
    (openlet probe-let)))

;;(define (call-any x) (+ x 21))
;;(display (call-any (probe-eval 42))) -> (+ 42 21) 63


;;; --------------------------------------------------------------------------------
;;;
#|
;;; other make-hook possibilities.  Here is the original:

(define make-hook
  (let ((+documentation+ "(make-hook . pars) returns a new hook (a function) that passes the parameters to its function list."))
    (lambda hook-args
      (let ((body ()))
        (apply lambda* hook-args
               (copy '(let ((result #<unspecified>))
                        (let ((hook (curlet)))
                          (for-each (lambda (hook-function) (hook-function hook)) body)
                          result))
                     :readable)
	       ())))))

;;; but hooks need an indication that a name passed as an argument is not a parameter name even when it is defined (in rootlet for example)
;;;   (define h (make-hook 'x)) (set! (hook-functions h) (list (lambda (hk) (set! (hk 'result) (hk 'abs))))) (h 123) -> abs
;;; but the current s7.c version is much faster than using copy, and surely copy isn't needed here; the current version returns #<undefined> for anything that
;;;  would otherwise be found in rootlet, but ideally we wouldn't have to create a new let, load up the fallback etc --
;;;  maybe add a flag on the let (blocked?) or notice let-ref-fallback in lets (as opposed to sublet), then it could be in the let with result.

;;; here is a macro make-hook:

(define-macro (make-hook . hook-args)
  `(let ((body ()))
     (lambda* ,(map (lambda (p) (if (pair? p) (cadr p) (if (keyword? p) p (error 'wrong-type-arg "make-hook arg ~S?" p)))) hook-args)
       (let ((result #<unspecified>))
         (let ((hook (openlet (sublet (curlet) 'let-ref-fallback (lambda (e sym) #<undefined>)))))
           (for-each (lambda (hook-function) (hook-function hook)) body)
           result)))))

;;; but this is much slower than the current apply lambda* version
|#

;;; --------------------------------------------------------------------------------

(define null-environment
  (let ((e #f))
    (lambda ()
      (or e
	  (set! e (let ((lt (inlet)))
		    (for-each (lambda (c)
				(if (and (or (procedure? (cdr c))
					     (macro? (cdr c)))
					 (not (constant? (car c))))
				    (varlet lt (car c) (symbol "[" (symbol->string (car c)) "]"))))
			      (rootlet))
		    (sublet lt)))))))

;;; (sandbox '(let ((x 1)) (+ x 2))) -> 3
;;; (sandbox '(let ((x 1)) (+ x 2) (exit))) -> #f

;;; perhaps tgsl's (immutable-let (rootlet))?
;;; perhaps use the blocking let?

(define sandbox
  (let ((+documentation+ "(sandbox code) evaluates code in an environment where nothing outside that code can be affected by its evaluation.")
	(built-ins
	 (let ((ht (make-hash-table))) ; bad guys removed
	   (for-each
	    (lambda (op)
	      (set! (ht op) #t))
	    '(symbol? gensym? keyword? let? openlet? iterator? macro? c-pointer? c-object? c-object-type immutable? constant?
	      input-port? output-port? eof-object? integer? number? real? complex? rational? random-state?
	      char? string? list? pair? vector? float-vector? int-vector? byte-vector? hash-table?
	      continuation? procedure? dilambda? boolean? float? proper-list? sequence? null? gensym
	      symbol->string string->keyword symbol->keyword byte-vector-ref byte-vector-set!
	      inlet sublet coverlet openlet let-ref let-set! make-iterator iterate iterator-sequence
	      iterator-at-end? provided? provide c-pointer c-pointer-type c-pointer-info port-line-number port-filename
	      pair-line-number pair-filename port-closed? let->list char-ready? flush-output-port
	      open-input-string open-output-string get-output-string quasiquote call-with-values multiple-value-bind
	      newline write display read-char peek-char write-char write-string read-byte write-byte
	      read-line read-string call-with-input-string with-input-from-string
	      call-with-output-string with-output-to-string
	      real-part imag-part numerator denominator even? odd? zero? positive?
	      negative? infinite? nan? complex magnitude angle rationalize abs exp log sin cos tan asin
	      acos atan sinh cosh tanh asinh acosh atanh sqrt expt floor ceiling truncate round lcm gcd
	      + - * / max min quotient remainder modulo = < > <= >= logior logxor logand lognot ash
	      random-state random inexact->exact exact->inexact integer-length make-polar make-rectangular
	      logbit? integer-decode-float exact? inexact? random-state->list number->string string->number
	      char-upcase char-downcase char->integer integer->char char-upper-case? char-lower-case?
	      char-alphabetic? char-numeric? char-whitespace? char=? char<? char>? char<=? char>=?
	      char-position string-position make-string string-ref string-set! string=? string<? string>?
	      string<=? string>=? char-ci=? char-ci<? char-ci>? char-ci<=? char-ci>=? string-ci=? string-ci<?
	      string-ci>? string-ci<=? string-ci>=? string-copy string-fill! list->string string-length
	      string->list string-downcase string-upcase string-append substring string object->string
	      format cons car cdr set-car! set-cdr! caar cadr cdar cddr caaar caadr cadar cdaar caddr
	      cdddr cdadr cddar caaaar caaadr caadar cadaar caaddr cadddr cadadr caddar cdaaar cdaadr
	      cdadar cddaar cdaddr cddddr cddadr cdddar assoc member list list-ref list-set! list-tail
	      make-list length copy fill! reverse reverse! sort! append assq assv memq memv vector-append
	      list->vector vector-fill! vector-length vector->list vector-ref vector-set! vector-dimension vector-dimensions
	      make-vector subvector vector float-vector make-float-vector float-vector-set! vector-rank
	      float-vector-ref int-vector make-int-vector int-vector-set! int-vector-ref string->byte-vector
	      byte-vector make-byte-vector hash-table make-hash-table hash-table-ref weak-hash-table
	      hash-table-set! hash-table-entries cyclic-sequences call/cc call-with-current-continuation
	      call-with-exit apply for-each map dynamic-wind values type-of
	      catch throw error documentation signature help procedure-source
	      setter arity aritable? not eq? eqv? equal? equivalent?
	      dilambda make-hook hook-functions stacktrace tree-leaves tree-memq tree-set-memq tree-cyclic? tree-count object->let
	      pi most-positive-fixnum most-negative-fixnum ; +nan.0 +inf.0 -nan.0 -inf.0
	      *stderr* *stdout* *stdin*
	      apply-values list-values
	      quote if begin let let* letrec letrec* cond case or and do set! unless when else
	      with-let with-baffle
	      lambda lambda* define define*
	      define-macro define-macro* define-bacro define-bacro* macroexpand)) ; not sure about macroexpand
	   ht))
	(baddies (list #_eval #_eval-string #_load #_autoload #_define-constant #_define-expansion #_require
		       #_string->symbol #_symbol->value #_symbol->dynamic-value #_symbol-table #_symbol #_keyword->symbol
		       #_defined?
		       #_call/cc #_gc #_read #_immutable!
		       #_open-output-file #_call-with-output-file #_with-output-to-file
		       #_open-input-file #_call-with-input-file #_with-input-from-file
		       #_current-output-port #_current-error-port #_current-input-port
		       #_set-current-output-port #_set-current-error-port #_set-current-input-port
		       #_varlet #_cutlet #_rootlet #_curlet #_owlet #_outlet #_funclet
		       #_exit #_emergency-exit #_dynamic_unwind
		       (reader-cond
			((provided? 'system-extras)
			 #_getenv #_system #_delete-file #_directory->list #_directory? #_file-exists? #_file-mtime))
		       )))
    (lambda (code)
      (if (tree-cyclic? code)
	  (error 'wrong-type-arg "sandbox argument is circular: ~S~%" code))
      (if (and (pair? code)
	       (>= (length code) 10000))
	  (error 'wrong-type-arg
		 (let-temporarily (((*s7* 'print-length) 16))
		   (format #f "sandbox code looks bogus: ~S~%" code))))
      ;; block any change to calling program, or access to files, etc
      (let ((new-code
	     (call-with-exit
	      (lambda (quit)
		(let walk ((tree code))
		  (cond ((symbol? tree)
			 (let ((val (symbol->value tree)))
			   ;; don't accept any symbol with an accessor
			   (if (or ;(setter val)
				   (setter tree)
				   (memq tree '(*s7* unquote abort))
				   (let? val))  ; not sure about this
			       (quit #f))
			   ;; don't accept anything except safe built-ins and local vars
			   (if (not (or (not (eq? (hash-table-ref built-ins tree) (*s7* 'hash-table-missing-key-value)))
					(eq? (symbol->value tree (outlet (funclet sandbox))) #<undefined>)))
			       (quit #f))
			   ;; if value is also in rootlet, check that it's safe (protect against (set! abs exit) sometime earlier)
			   (if (or (procedure? val)
				   (macro? val))
			       (let ((unval (symbol->value tree (sublet (rootlet) (unlet))))) ; unlet returns the new unshadowing let
				 (if (not (eq? val unval))
				     (quit #f))))
			   tree))

			((memq tree baddies)  ; if tree is a bad procedure (probably via #_) quit
			 (quit #f))

			((not (pair? tree))
			 tree)

			((eq? 'quote (car tree)) ; tree-cyclic? ignores quoted lists
			 (if (tree-cyclic? (cdr tree))
			     (error 'wrong-type-arg "sandbox argument is circular: ~S~%" tree))
			 tree)

			(else
			 ;; do we need to check IO ports and set! here?
			 (cons (walk (car tree))
			       (walk (cdr tree))))))))))
	(and new-code
	     ;; make sure *s7* will not call any outside code upon error, clear out readers, etc
	     (let-temporarily ((*#readers* ())
			       (*libraries* ())
			       ((*s7* 'max-stack-size) 10000) ; block infinite recursion
			       ((*s7* 'autoloading?) #f)      ; turn off the autoloader
			       ((hook-functions *unbound-variable-hook*) ())
			       ((hook-functions *missing-close-paren-hook*) ())
			       ((hook-functions *load-hook*) ())
			       ((hook-functions *error-hook*) ())
			       ((hook-functions *read-error-hook*) ())
			       ((hook-functions *rootlet-redefinition-hook*) ())
			       (reader-cond ((not (provided? 'pure-s7))
					     ((current-output-port) *stdout*)
					     ((current-error-port) *stderr*))))
	       (let-temporarily (((*s7* 'expansions?) #f))   ; turn off read-time macro expansion
		 (catch #t
		   (lambda ()
		     (eval new-code (sublet (rootlet) (unlet))))
		   (lambda args
		     (format #f "error: ~A"
			     (catch #t
			       (lambda ()
				 (apply format #f (cadr args)))
			       (lambda args
				 (copy "?")))))))))))))