I know that cons returns a seq and conj returns a collection. I also know that conj "adds" the item to the optimal end of the collection, and cons always "adds" the item to the front. This example illustrates both of these points:

user=> (conj [1 2 3] 4) //returns a collection
[1 2 3 4]
user=> (cons 4 [1 2 3]) //returns a seq
(4 1 2 3)

For vectors, maps, and sets these differences make sense to me. However, for lists they seem identical.

user=> (conj (list 3 2 1) 4) //returns a list
(4 3 2 1)
user=> (cons 4 (list 3 2 1)) //returns a seq
(4 3 2 1)

Are there any examples using lists where conj vs. cons exhibit different behaviors, or are they truly interchangeable? Phrased differently, is there an example where a list and a seq cannot be used equivalently?


One difference is that conj accepts any number of arguments to insert into a collection, while cons takes just one:

(conj '(1 2 3) 4 5 6)
; => (6 5 4 1 2 3)

(cons 4 5 6 '(1 2 3))
; => IllegalArgumentException due to wrong arity

Another difference is in the class of the return value:

(class (conj '(1 2 3) 4))
; => clojure.lang.PersistentList

(class (cons 4 '(1 2 3))
; => clojure.lang.Cons

Note that these are not really interchangeable; in particular, clojure.lang.Cons does not implement clojure.lang.Counted, so a count on it is no longer a constant time operation (in this case it would probably reduce to 1 + 3 -- the 1 comes from linear traversal over the first element, the 3 comes from (next (cons 4 '(1 2 3)) being a PersistentList and thus Counted).

The intention behind the names is, I believe, that cons means to cons(truct a seq)1, whereas conj means to conj(oin an item onto a collection). The seq being constructed by cons starts with the element passed as its first argument and has as its next / rest part the thing resulting from the application of seq to the second argument; as displayed above, the whole thing is of class clojure.lang.Cons. In contrast, conj always returns a collection of roughly the same type as the collection passed to it. (Roughly, because a PersistentArrayMap will be turned into a PersistentHashMap as soon as it grows beyond 9 entries.)

1 Traditionally, in the Lisp world, cons cons(tructs a pair), so Clojure departs from the Lisp tradition in having its cons function construct a seq which doesn't have a traditional cdr. The generalised usage of cons to mean "construct a record of some type or other to hold a number of values together" is currently ubiquitous in the study of programming languages and their implementation; that's what's meant when "avoiding consing" is mentioned.

  • 1
    What a fantastic writeup! I was unaware that there was a Cons type. Well done! – Daniel Yankowsky Jun 9 '10 at 21:18
  • Thanks. Happy to hear that. :-) – Michał Marczyk Jun 9 '10 at 21:25
  • 2
    Incidentally, as a special case, (cons foo nil) returns a singleton PersistentList (and likewise for conj). – Michał Marczyk Jun 9 '10 at 21:30
  • 1
    Another superb explanation. You truly are a clojure jedi! – dbyrne Jun 9 '10 at 22:47
  • 1
    In my experience, treating lists as lists and not as seqs ias important when performance matters. – cgrand Jun 10 '10 at 14:02

My understanding is that what you say is true: conj on a list is equivalent to cons on a list.

You can think of conj as being an "insert somewhere" operation, and cons as being an "insert at the head" operation. On a list, it is most logical to insert at the head, so conj and cons are equivalent in this case.


Another difference is that because conj takes a sequence as the first argument, it plays nicely with alter when updating a ref to some sequence:

(dosync (alter a-sequence-ref conj an-item))

This basically does (conj a-sequence-ref an-item) in a thread-safe manner. This wouldn't work with cons. See the chapter on Concurrency in Programming Clojure by Stu Halloway for more info.


Another difference is the behavior of list?

(list? (conj () 1)) ;=> true
(list? (cons 1 ())) ; => false
  • 4
    cons always returns a sequence which conj returns the same type of the one provided – Ning Sun Jan 27 '14 at 7:55

There are dedicated functions in the Tupelo Library to add append or prepend values to any sequential collection:

(append [1 2] 3  )   ;=> [1 2 3  ]
(append [1 2] 3 4)   ;=> [1 2 3 4]

(prepend   3 [2 1])  ;=> [  3 2 1]
(prepend 4 3 [2 1])  ;=> [4 3 2 1]

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.