This is my lisp code.
(defun f (lst)
(append (subst (last lst) (first lst) (car lst))
(subst (first lst) (last lst) (cdr lst)))
)
(f '(a b c d))
This code's output is (D B C . A)
The function works well, but it does not finish because of symbol.
I want make (D B C A) without symbol.
How do I fix it? Or is there a better way?
I would appreciate a help.
Assuming that you are meaning to do something like this, you could try using rotatef:
? (setf lst '(a b c d))
(A B C D)
? lst
(A B C D)
? (rotatef (nth 0 lst) (nth (- (length lst) 1) lst))
;Compiler warnings :
; In an anonymous lambda form at position 0: Undeclared free variable LST (3 references)
NIL
? lst
(D B C A)
Assuming you want to swap the first and last elements, here is an implementation which does that. It traverses the list three times and copies it twice: it is possible to do much better than this, but not without being reasonably devious (in particular I'm reasonably sure a naive implementation with rotatef also traverses it three times although it only copies it once as you need an initial copy of the list, since rotatef is destructive):
(defun swapify (list)
;; swap the first and last elements of list
(if (null (rest list))
list
(cons (first (last list)) ; 1st traversal
(append (butlast (rest list)) ; 2nd and third traversals
(list (first list))))))
And here is the devious implementation which traverses the list exactly once. This relies on tail-call elimination: a version which uses a more straightforward loop is fairly obvious.
(defun swapify (list)
;; return a copy of list with the first and last elements swapped
(if (null (rest list))
list
(let ((copy (cons nil nil)))
(labels ((walk (current tail)
(if (null (rest tail))
(progn
(setf (first copy) (first tail)
(rest current) (cons (first list) nil))
copy)
(progn
(setf (rest current) (cons (first tail) nil))
(walk (rest current) (rest tail))))))
(walk copy (rest list))))))
the symbol is because you are appending a list to an element, if you turn the element into a list using: (list (car lst)) with the same code and it will no longer have the symbol.
Related
I have to make a recursive function in lisp which takes a list and makes another list with only the elements on odd position in the given list.
If I have (1 2 3 4 5) I have to output (1 3 5)
I have a code here:
(defun pozpar(lst) (do(
(l lst (cddr l))
(x '() (cons x (car l))))
((null l) x)))
This outputs:
(5 3 1)
I know cons adds the elements at the beginning and I tried with append or list but nothing worked.
I think this is a way easier solution:
(defun popzar (lst)
(cond ((null lst) nil)
(t (cons (car lst)
(popzar (cdr (cdr lst)))))))
It first checks if the list is empty and if not it creates a new list with the first element and the result of calling itself again with the rest of the list except for the second element.
The easiest way is to reverse the result:
(defun pozpar (lst)
(do ((l lst (cddr l))
(x '() (cons (car l) x)))
((null l)
(nreverse x))))
(pozpar '(1 2 3 4 5))
==> (1 3 5)
Notes
This returns, not outputs the value you want.
Prepending values and reverting the result is a common Lisp coding pattern.
Since append is linear in the length of its argument, using it in a loop produces quadratic code.
I formatted the code in the standard Lisp way. If you use this style, lispers will have an easier time reading your code, and, consequently, more willing to help you.
With using loop it's very easy to get the elements in the order you processed them. It is also the most effective and the only one guaranteed to work with all length arguments:
(defun pozpar1 (lst)
(loop :for e :in lst :by #'cddr
:collect e)))
If you really want recursion I would have done it with an accumulator with a linear update reverse in the end:
(defun pozpar2 (lst)
(labels ((helper (lst acc)
(if (endp lst)
(nreverse acc)
(helper (cddr lst) (cons (car lst) acc)))))
(helper lst '())))
However a classical not tail recursive version would look like this:
(defun pozpar3 (lst)
(if (endp lst)
'()
(cons (car lst) (pozpar3 (cddr lst)))))
I'm new to LISP so I'm not very good at this... So my problem is, I've been given a structure (list of lists) and my job is to create a function that retrives the second item in each sub list (counting from 0). So in the end I would like to return (fruit fruit agent yard).
I can do the basic recursion calls that goes through the lists but I can't seem to figure out how to get the second item in the sub list.
Structure of the lists:
(defparameter *jack*
'((orange#8 apple fruit basment)
(pear#12 mango fruit basment)
(jones rabbit agent closet)
(jack dog agent yard)
))
Code I have so far:
(defun attempt(*data*)
(cond ((null *data*)
nil
)
((attempt (rest *data*)))
))
What I'm thinking is that I should be iterating through the list sub lists using first and rest but like I said, I can't figure it out. Help?
CL-USER> (mapcar #'caddr *jack*)
(FRUIT FRUIT AGENT AGENT)
EDIT: If you want to practise your recursive approach, try:
(defun attempt (list-of-lists)
(if (null list-of-lists) nil
(cons (third (car list-of-lists))
(attempt (cdr list-of-lists)))))
EDIT2: Tail-recursively:
(defun attempt-tail (list-of-lists)
(labels ((iter (rest ans)
(if (null rest) (nreverse ans)
(iter (cdr rest) (push (third (car rest)) ans)))))
(iter list-of-lists nil)))
EDIT3: While I'm at it, here's the loop version:
(loop for list in *jack* collect (third list))
This is most probably what you are looking for:
(mapcar #'cadr *jack*)
yes you can define for this process you want a tail-recursive procedure;
(defun nths (n l)"returns list of nths of a list of lists l"
(nths-aux n l '()))
(defun nths-aux (n l A)
(if (null l) A;or (reverse A)
(nths-aux n (cdr l) (cons (nth n (car l)) A))))
This question already has answers here:
Flatten a list using only the forms in "The Little Schemer"
(3 answers)
Closed 9 years ago.
If I have an s expression, for example '(1 2 (3) (4 (5)) 6 7), how would I convert that into a list like (1 2 3 4 5 6 7)? I basically need to extract all of the atoms from the s expression. Is there a built in function that would help me do it?
(define (convert-to-list s) ... )
My algorithm so far is, if the first element is an atom append it onto a list. If the first element is a list then get the car of that element and then call the function (convert-to-list) with that function so it catches the base case of the recursion. And append the cdr of that list being invoked on convert-to-list to car of it. I'm trying to teach myself scheme from Structure and Interpretation of Computer Programs and I'm just trying out random things. Doing this recursively is proving to be more difficult than I anticipated.
To literally answer your question, "Is there a built in function to help me do this?", in Racket yes there is. flatten does exactly this: "Flattens an arbitrary S-expression structure of pairs into a list."
Examples:
> (flatten '((a) b (c (d) . e) ()))
'(a b c d e)
> (flatten 'a)
'(a)
However it's a great exercise to think about how you would write flatten yourself.
Chris Jester-Young's comment has a link to an elegant way. If she'd posted that as an answer, instead of as a comment, I'd suggest marking her answer as accepted, not mine. :)
Your algorithm doesn't look bad, it's just missing a step or two.
(define (flatten lst) ; 'flatten' is a better name for this function IMO
(cond
((null lst) nil)
;; Don't worry that I'm calling (flatten (cdr lst)) without any checking;
;; the above case handles it
((atom (car lst)) ; The car's okay
(cons (car lst) (flatten (cdr lst))))
((cons? (car lst)) ; The car still needs flattening; note the use of
; 'append' here (the car-list may have any number of elements)
(append (flatten (car lst)) (flatten (cdr lst))))))
Between the (flatten (car lst)) calls dealing with the first element and the (flatten (cdr lst)) calls recursively dealing with the rest of the list, the input list ends up a flat list (i.e. no elements are conses).
(Warning: I'm not a Scheme guru; the above code may contain errors.)
Your cases should cover the empty list, an atom, (car s) being an atom, and (car s) being a list.
This works, though I bashed out a list append function because I didn't remember what the built-in one was. Works in Racket Advanced Student.
(define (list-glue left-list right-list)
(cond
((null? left-list) right-list)
(else (cons (car left-list) (list-glue (cdr left-list) (right-list))))))
(define (convert-to-list s)
(cond
((null? s) '())
((not (list? s)) (cons s (quote ())))
((not (list? (car s))) (cons (car s) (convert-to-list (cdr s))))
(else
(list-glue
(convert-to-list (car s))
(convert-to-list (cdr s))))))
Now, if you want a faster implementation, you don't need append at all.
The idea is to pass around what you would append onto as a parameter. I call this tail.
If you have an empty s-exp, you just return the tail, since there is nothing to add to it.
I've got the code, flat and flat2, where flat uses a match statement, things in racket, and flat2 just uses a cond, which I find a little harder to read, but I provide it in case you haven't seen match yet.
#lang racket
(define (flat s-exp tail)
(match s-exp
['() tail]
[(cons fst rst)
(let ([new-tail (flat rst tail)])
(flat fst new-tail))]
[atom
(cons atom tail)]))
(define (flat
(cond
[(empty? s-exp) tail]
[(list? s-exp)
(let* ([fst (first s-exp)]
[rst (rest s-exp)]
[new-tail (flat])
(flat fst new-tail))]
[#t
(cons s-exp tail)]))
To use them, call them like so (flat '(1 () (2 (3)) 4) '()) ===> '(1 2 3 4).
You need to supply the empty list for them to start off on.
This can be done simply by recursing on sublists and rest-lists. You can see how easily this code reads. Like such:
(define (convert-to-list list)
(if (null? list)
'()
(let ((next (car list))
(rest (cdr list)))
(if (list? next)
(append (convert-to-list next) (convert-to-list rest))
(cons next (convert-to-list rest))))))
> (convert-to-list '(a b c))
(a b c)
> (convert-to-list '((a b) (((c d) e f) g h) i j))
(a b c d e f g h i j)
>
I would like to write a function that reverses the elements of a list, but it should happen in place (that is, don't create a new reversed list).
Something like:
>> (setq l ' (a b c d))
((a b c d)
>> (rev l)
(d c b a)
>> l
(d c b a)
What flags should I follow to achieve this?
Have a look at nreverse which will modify the list in place (see HyperSpec).
As per the comments, do note the comments that #Barmar made and this bit from the spec:
For nreverse, sequence might be destroyed and re-used to produce the result. The result might or might not be identical to sequence. Specifically, when sequence is a list, nreverse is permitted to setf any part, car or cdr, of any cons that is part of the list structure of sequence.
It's not difficult to implement this (ignoring fault cases). The keys are to use (setf cdr) to reuse a given cons cell and not to lose the reference to the prior cdr.
(defun nreverse2 (list)
(recurse reving ((list list) (rslt '()))
(if (not (consp list))
rslt
(let ((rest (cdr list)))
(setf (cdr list) rslt)
(reving rest list)))))
(defmacro recurse (name args &rest body)
`(labels ((,name ,(mapcar #'car args) ,#body))
(,name ,#(mapcar #'cadr args))))
[edit] As mentioned in a comment, to do this truly in-place (and w/o regard to consing):
(defun reverse-in-place (l)
(let ((result l))
(recurse reving ((l l) (r (reverse l))
(cond ((not (consp l)) result)
(else (setf (car l) (car r))
(reving (cdr l) (cdr r)))))))
> (defvar l '(1 2 3))
> (reverse-in-place l))
(3 2 1)
> l
(3 2 1)
How can I remove nested parentheses recursively in Common LISP Such as
(unnest '(a b c (d e) ((f) g))) => (a b c d e f g)
(unnest '(a b)) => (a b)
(unnest '(() ((((a)))) ())) => (a)
Thanks
Here's what I'd do:
(ql:quickload "alexandria")
(alexandria:flatten list)
That works mainly because I have Quicklisp installed already.
(defun flatten (l)
(cond ((null l) nil)
((atom l) (list l))
(t (loop for a in l appending (flatten a)))))
I realize this is an old thread, but it is one of the first that comes up when I google lisp flatten. The solution I discovered is similar to those discussed above, but the formatting is slightly different. I will explain it as if you are new to lisp, as I was when I first googled this question, so it's likely that others will be too.
(defun flatten (L)
"Converts a list to single level."
(if (null L)
nil
(if (atom (first L))
(cons (first L) (flatten (rest L)))
(append (flatten (first L)) (flatten (rest L))))))
For those new to lisp, this is a brief summary.
The following line declares a function called flatten with argument L.
(defun flatten (L)
The line below checks for an empty list.
(if (null L)
The next line returns nil because cons ATOM nil declares a list with one entry (ATOM). This is the base case of the recursion and lets the function know when to stop. The line after this checks to see if the first item in the list is an atom instead of another list.
(if (atom (first L))
Then, if it is, it uses recursion to create a flattened list of this atom combined with the rest of the flattened list that the function will generate. cons combines an atom with another list.
(cons (first L) (flatten (rest L)))
If it's not an atom, then we have to flatten on it, because it is another list that may have further lists inside of it.
(append (flatten (first L)) (flatten (rest L))))))
The append function will append the first list to the start of the second list.
Also note that every time you use a function in lisp, you have to surround it with parenthesis. This confused me at first.
You could define it like this for example:
(defun unnest (x)
(labels ((rec (x acc)
(cond ((null x) acc)
((atom x) (cons x acc))
(t (rec (car x) (rec (cdr x) acc))))))
(rec x nil)))
(defun flatten (l)
(cond ((null l) nil)
((atom (car l)) (cons (car l) (flatten (cdr l))))
(t (append (flatten (car l)) (flatten (cdr l))))))
Lisp has the function remove to remove things. Here I use a version REMOVE-IF that removes every item for which a predicate is true. I test if the thing is a parenthesis and remove it if true.
If you want to remove parentheses, see this function:
(defun unnest (thing)
(read-from-string
(concatenate
'string
"("
(remove-if (lambda (c)
(member c '(#\( #\))))
(princ-to-string thing))
")")))
Note, though, as Svante mentions, one does not usually 'remove' parentheses.
Most of the answers have already mentioned a recursive solution to the Flatten problem. Using Common Lisp Object System's multiple dispatching you could solve the problem recursively by defining 3 methods for 3 possible scenarios:
(defmethod flatten ((tree null))
"Tree is empty list."
())
(defmethod flatten ((tree list))
"Tree is a list."
(append (flatten (car tree))
(flatten (cdr tree))))
(defmethod flatten (tree)
"Tree is something else (atom?)."
(list tree))
(flatten '(2 ((8) 2 (9 (d (s (((((a))))))))))) ; => (2 8 2 9 D S A)
Just leaving this here as I visited this question with the need of only flattening one level and later figure out for myself that (apply 'concatenate 'list ((1 2) (3 4) (5 6 7))) is a cleaner solution in that case.
This is a accumulator based approach. The local function %flatten keeps an accumulator of the tail (the right part of the list that's already been flattened). When the part remaining to be flattened (the left part of the list) is empty, it returns the tail. When the part to be flattened is a non-list, it returns that part prefixed onto the tail. When the part to be flattened is a list, it flattens the rest of the list (with the current tail), then uses that result as the tail for flattening the first part of the list.
(defun flatten (list)
(labels ((%flatten (list tail)
(cond
((null list) tail)
((atom list) (list* list tail))
(t (%flatten (first list)
(%flatten (rest list)
tail))))))
(%flatten list '())))
CL-USER> (flatten '((1 2) (3 4) ((5) 6) 7))
(1 2 3 4 5 6 7)
I know this question is really old but I noticed that nobody used the push/nreverse idiom, so I am uploading that here.
the function reverse-atomize takes out each "atom" and puts it into the output of the next call. At the end it produces a flattened list that is backwards, which is resolved with the nreverse function in the atomize function.
(defun reverse-atomize (tree output)
"Auxillary function for atomize"
(if (null tree)
output
(if (atom (car tree))
(reverse-atomize (cdr tree) (push (car tree) output))
(reverse-atomize (cdr tree) (nconc (reverse-atomize (car tree)
nil)
output)))))
(defun atomize (tree)
"Flattens a list into only the atoms in it"
(nreverse (reverse-atomize tree nil)))
So calling atomize '((a b) (c) d) looks like this:
(A B C D)
And if you were to call reverse-atomize with reverse-atomize '((a b) (c) d) this would occur:
(D C B A)
People like using functions like push, nreverse, and nconc because they use less RAM than their respective cons, reverse, and append functions. That being said the double recursive nature of reverse-atomize does come with it's own RAMifications.
This popular question only has recursive solutions (not counting Rainer's answer).
Let's have a loop version:
(defun flatten (tree &aux todo flat)
(check-type tree list)
(loop
(shiftf todo tree nil)
(unless todo (return flat))
(dolist (elt todo)
(if (listp elt)
(dolist (e elt)
(push e tree))
(push elt flat))))))
(defun unnest (somewhat)
(cond
((null somewhat) nil)
((atom somewhat) (list somewhat))
(t
(append (unnest (car somewhat)) (unnest (cdr somewhat))))))
I couldn't resist adding my two cents. While the CL spec does not require tail call optimization (TCO), many (most?) implementations have that feature.
So here's a tail recursive version that collects the leaf nodes of a tree into a flat list (which is one version of "removing parentheses"):
(defun flatten (tree &key (include-nil t))
(check-type tree list)
(labels ((%flatten (lst accum)
(if (null lst)
(nreverse accum)
(let ((elem (first lst)))
(if (atom elem)
(%flatten (cdr lst) (if (or elem include-nil)
(cons elem accum)
accum))
(%flatten (append elem (cdr lst)) accum))))))
(%flatten tree nil)))
It preserves null leaf nodes by default, with the option to remove them. It also preserves the left-to-right order of the tree's leaf nodes.
Note from Google lisp style guide about TCO:
You should favor iteration over recursion.
...most serious implementations (including SBCL and CCL) do implement proper tail calls, but with restrictions:
The (DECLARE (OPTIMIZE ...)) settings must favor SPEED enough and not favor DEBUG too much, for some compiler-dependent meanings of "enough" and "too much".
And this from SBCL docs:
... disabling tail-recursion optimization ... happens when the debug optimization quality is greater than 2.