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I'm looking for the best way to implement multidimensional associative arrays in Common Lisp. I'm using SBCL.

For example in MATLAB, I can create a struct array like this, eg. with some geographical data:

my_array.Finland.capital = 'Helsinki';
my_array.Finland.northernmost_municipality = 'Utsjoki';
my_array.Norway.capital = 'Oslo';

And then refer to it using dynamic field names:

country = 'Finland';
city_status = 'capital';

my_array.(country).(city_status)

would give the string 'Helsinki' as a result.

So, what would be the best way to implement multidimensional (n-dimensional) associative arrays in Common Lisp? (as in the above example in MATLAB)

I found a working solution based on converting the values/keys (given as strings) to numeric addresses using a hash table, and then passing those numeric address to aref as indices to a multidimensional array. But I wonder is there some better way to do it? I need to convert strings to other strings, strings to lists and strings to numbers (as in the example below).

My solution is this (with an example data to convert numbers written in English to their numeric representation):

Function list-to-3d-array below is a minimally modified version of Rainer Joswig's answer to Common Lisp: convert between lists and arrays .

;;; functions.
(defun list-to-3d-array (my-list)
  (make-array (list (length my-list)
                    (length (first my-list))
                    (length (first (first my-list))))
              :initial-contents my-list))

(defun prepare-hash-table (my-hash-table factor-name factor-values-list)
  "This function stores values from 0 to n for the keys created by concatenating the factor-name and the values given in a list."
  (loop for i from 0 to (1- (length factor-values-list))
        do (setf (gethash (concatenate 'string factor-name "-" (nth i factor-values-list)) my-hash-table) i)))

(defun return-value-from-assoc-array (my-array my-hash-table hundreds tens ones)
  (aref my-array
        (gethash (concatenate 'string "hundreds-" hundreds) my-hash-table)
        (gethash (concatenate 'string "tens-" tens) my-hash-table)
        (gethash (concatenate 'string "ones-" ones) my-hash-table)))
;;; functions end here.

;;; some example data.
(defparameter *array-contents*
  (list 
    (list
      (list 111 112 113)
      (list 121 122 123)
      (list 131 132 133))
    (list
      (list 211 212 213)
      (list 221 222 223)
      (list 231 232 233))
    (list
      (list 311 312 313)
      (list 321 322 323)
      (list 331 332 333))))

(defparameter *hundreds-in-english* (list "hundred" "twohundred" "threehundred"))
(defparameter *tens-in-english* (list "ten" "twenty" "thirty"))
(defparameter *ones-in-english* (list "one" "two" "three"))

(defparameter *my-hash-table* (make-hash-table :test 'equal))
;;; example parameters end here.

;;; prepare the array.
(defparameter *my-array* (list-to-3d-array *array-contents*))

;;;; prepare the hash table.
(prepare-hash-table *my-hash-table* "hundreds" *hundreds-in-english*)
(prepare-hash-table *my-hash-table* "tens" *tens-in-english*)
(prepare-hash-table *my-hash-table* "ones" *ones-in-english*)

Then eg. (return-value-from-assoc-array *my-array* *my-hash-table* "hundred" "ten" "two") outputs:

112
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3 Answers 3

up vote 4 down vote accepted

I disagree with the design and implementation of get-nested-hash given above. (get-nested-hash 1) should not return 1, and (get-nested-hash 1 2) should not return nil. Not passing two arguments should be an error. Multiple values should be returned in order to distinguish intentional nils, like gethash. The loop is messy and cumbersome. A correctable error should not be issued via check-type because data loss could result.

Here is an improved solution:

(defun rec-hash (rec-hash key &rest more-keys)
  (if more-keys
      (apply #'rec-hash (gethash key rec-hash) more-keys)
      (gethash key rec-hash)))

(defun auto-vivify (rec-hash key)
  (multiple-value-bind (child exist) (gethash key rec-hash)
    (if exist
        child
        (setf (gethash key rec-hash)
              (make-hash-table :test (hash-table-test rec-hash))))))

(defun (setf rec-hash) (value rec-hash key &rest more-keys)
  (if more-keys
      (apply #'(setf rec-hash) value (auto-vivify rec-hash key) more-keys)
      (setf (gethash key rec-hash) value)))
share|improve this answer
1  
ah, this is very nice :) I didn't know one could #'(setf ..), that's great! –  Lex Dec 9 '12 at 10:48
    
I'm new to Common Lisp. Could someone explain to me what #'(setf ...) means? Also, I tried it on ECL here, and it gave me an error for that. –  Paulo Torrens Oct 9 '13 at 22:11

For this, you would probably want to use nested hash tables, for example:

(defparameter *my-table* (make-hash-table :test #'equalp))
;; => *MY-TABLE*

(setf (get-nested-hash *my-table* "Finland" "Capital") "Helsinki")
;; => "Helsinki"

(get-nested-hash *my-table* "Finland" "Capital")
;; => "Helsinki"

Here's an example implementation, though I know it may be hard to follow, especially for someone new to the language (sorry short on time at the moment, bad formatting and explanations :P ):

(defun get-nested-hash (hash-table &rest keys)
  "look up keys in nested hash-table, or nil"
  (if keys
      (when (typep hash-table 'hash-table)
         (apply #'get-nested-hash (gethash (car keys) hash-table) (cdr keys)))      
      hash-table))

(defun (setf get-nested-hash) (value hash-table &rest keys)
  (if keys
      (let (;;we'll use a cursor to walk through the nested
        ;;hash tables along the keys
        (cursor hash-table)
        ;;different hash tables can have different
        ;;test functions. we hold on to this so any nested
        ;;tables we create behave the same as the original
        (test (hash-table-test hash-table)))
    (loop
       ;;for ... on binds subsequent cdrs, or sublists
       ;;until they run out.
       for ks on keys 

       ;;make sure the cursor is a hash table
       do (check-type cursor hash-table)

       ;;if there are more keys left after this one...
       if (cdr ks) do
         (let* (;;get this key
            (key (car ks))
            ;;and look up the next level
            (next (gethash key cursor)))
           ;;if there is no next level
           (unless next
         (setf
          ;;replace it with a new hash table
          next (make-hash-table :test test)
          ;;and store it back into the cursor
          (gethash key cursor) next))

           ;;either way, advance the cursor
           (setf cursor next))

       ;;if there are no keys after this one,
       ;;then store the new value into the cursor.
       else do
         (setf (gethash (car ks) cursor) value)

       finally
         (return value)))
      ;;oops!
      (error "no keys provided")))

I'd suggest playing around with it a bit, making it error out, and tweaking it's behavior to your liking. If you haven't run into http://www.gigamonkeys.com/book/ yet, I highly recommend it :)

share|improve this answer
    
This works nicely. Practical Common Lisp is indeed a very good book and I use it all the time (together with Paradigms of Artificial Intelligence Programming and ANSI Common Lisp). –  nrz Nov 29 '12 at 16:02
    
PCL is great. I bought a hard copy, learned it, and passed it on :) –  Lex Dec 1 '12 at 2:08
    
This is a nice abstraction IMO. Do you know of a CL package that provides this sort of get-nested-hash, that is quicklisp installable? –  Clayton Stanley Dec 1 '12 at 6:19
    
@ClaytonStanley not offhand. seems like the kind of thing that'd be good for github.com/tarballs-are-good/quickutil once it's ready –  Lex Dec 1 '12 at 15:43
    
Thanks for the link. That's an interesting project. Seems like being able to express dependencies at the function level could certainly be useful for certain applications. –  Clayton Stanley Dec 1 '12 at 20:27

You can also use a Prolog implementation in Lisp. Prolog provides relations and the possibility to assert facts and one can use logic rules.

Here a simple relation in LispWorks:

==> (defrel capital ((capital finland helsinki)))
YES.
OK.

==> (capital finland ?city)

?CITY = HELSINKI
OK.

==> (and (= ?country finland) (capital ?country ?city))

?COUNTRY = FINLAND
?CITY = HELSINKI
OK.

Typically such a Prolog in Lisp then also provides access between Lisp and the embedded Prolog.

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