Sorry for the long question. I decided to explain the context of the problem first as maybe there are other solutions to my problem. If you're in a hurry, just read THE QUESTION below.

(EDITED -- In the mean time I added some attempts to solve the problem. The fourth one has my final conclusion, you can jump straight to it.)


I have a hash table filled with roughly 20k pairs (key(i),value(i)). I want to generate random lists like this one


The restriction is that once I've chosen key(213) to be the first element of the list, not all keys can follow it (I have some other function 'decide' which can decide whether some key can be the next one in the list or not). So, I'd like to choose a random next element and check if it's appropriate -- in the example above key(127) was chosen. In the case that that element is rejected by my 'decide' function I'd like to pick another one randomly. But I wouldn't want to pick the same just rejected because I know it will be rejected again and not only would this be inefficient, I also run the risk, if only a few keys can be the next ones, of taking a long time until I find an appropriate key. Note that there can be repetition, such as


This is OK, as long as the 'decide' function accepts key(213) as the next in the list. So, all I need is a way to randomly enumerate the (key,value) pairs in the hash table. Whenever I have to choose a key, I create an enumeration, which I consume by checking each new element with the 'decide' function (so, no repetitions occur) and when I find one I add it to the list and proceed incrementing the list. The thing is that I don't want this enumeration of the hash table to be the same every time. I want it to be random. (This has to do with the structure of the search space I have in my particular problem which is not relevant here.)

I can of course implement this by generating random integers and using just lists -- that's what I'm currently doing. But, as this is something I run into quite frequently, I wonder if there is some random enumeration facility for hash tables somewhere.


Is there some random enumeration function for hash tables somewhere? I am aware of the function BatHashtbl.enum (Batteries library) but I think it will always give me the same enumeration for the same hash table (is this correct?). Also, there doesn't seem to exist anything of the sort in that BatHashtbl module. I'd be interested in something like

random_enum: ('a, 'b) t -> int -> ('a * 'b) Enum.t

which, when provided with a hash table and some integer as a seed for the random generator, will give a different random enumeration of the hash table. Any ideas?

Thanks for any help!

Best, Surikator.


After Niki's suggestion in the comments, and looking in more detail through the Batteries Library, I've come up with this

let rand_enum ht n =
BatRandom.init n;
let hte = BatHashtbl.enum ht
in let s = BatRandom.shuffle hte (* This returns*)
in Array.to_list s

which has the type

val rand_enum : ('a,'b) BatHashtbl.t -> int -> ('a*'b) list

It uses the Fisher-Yates algorithm for the shuffling which runs in O(n). It returns a list instead of an enumeration and that is quite annoying, because it means that even if I'm happy with the third element of the list obtained with rand_enum, the function will still compute a random enumeration for the whole 20k elements in the hash table.

Best, Surikator


I defined the module RndHashtblEnum as

(* Random Hashtable Enumeration Module *)
type ('a,'b) t = {
   ht:('a,'b) BatHashtbl.t;
   mutable ls:('a*'b) list;
   f: (('a,'b) BatHashtbl.t -> ('a*'b) list)}

let shuffle ht =
  let hte = BatHashtbl.enum ht
  in let s = BatRandom.shuffle hte
  in Array.to_list s

let create ht n = (BatRandom.init n; {ht=ht;ls=shuffle ht;f=shuffle})

let rec next re =
match re.ls with
    | [] -> re.ls<-(re.f re.ht);next re
    | h::t -> re.ls<-t; h

It has the new type t for random enumerations of hash tables. This type stores the hash table we wish to enumerate, the list we will be enumerating from and a function to compute a new enumerated list (from the hash table) once the list we have runs out. Once the list has run out, when we ask for a new random element of the hash table, the type t automatically puts a new random list created from the hash table.

So, using the above module, if we want to enumerate a hash table randomly, we simply do:

let re = RndHashtblEnum.create ht 1236

to create a random enumeration of hash table ht with random seed 1236 (In this code I assume the hash table was defined before) and we can then write

let (k,v) = RndHashtblEnum.next re

to get the next (k,v) pair from the random enumeration.

One question we may ask is whether this is actually fair randomness because I use the remaining of the list to randomly enumerate the hash table the next time I need a random enumeration. Well, it isn't. If my hash table has say 1000 elements and after extracting 5 random ones I am satisfied with the result, I know that in the next 995 (of the second set of extractions) none of those 5 elements will be extracted. So, that's not fair randomness. It's even worse. It may well be the case that in the next 1000 extractions (995 from this list, 5 from the next enumerating list) some elements will not be covered. On average, the algorithm is fair, but it isn't fair all the time.

Best, Surikator.


Hi again,

Including Niki's suggestion of using BatArray.enum and a fundamental change in the stochastic part of the algorithm, I have come up with a new improved version of the RndHashtblEnum module. The suggestion is:

(* Improved Random Hashtable Enumeration Module *)
type ('a,'b) t = {ht:('a,'b) BatHashtbl.t; mutable enum:('a*'b) BatEnum.t; enum0: ('a*'b) BatEnum.t}

let shuffle ht =
let hte = BatHashtbl.enum ht
in let s = BatRandom.shuffle hte
in BatArray.enum s

let create ht n =
let e = shuffle ht
in (BatRandom.init n; {ht=ht;enum=BatEnum.clone e;enum0=e})

let rec next re =
match BatEnum.get re.enum with
    | None -> re.enum<-re.enum0; next re
    | Some e -> e

This new module gets rid of the (silly) costs of passing an array to a list and only uses the Fisher-Yates algorithm once at the start -- so, in the long run, we can consider the contribution of the Fisher-Yates bit to be O(1).

The new version is now fair in terms of randomness. This is not so easy to see and it took me a bit to realize that. Suppose the hash table has 1000 entries. In the new version, we always use the same enumeration (enum0 -- fixed when we create the random enumeration with the "create" function). This means that, when trying to find the next element in our final list, since some key in the hash table will have to satisfy the "decide" function (otherwise we would couldn't continue with the algorithm and we would just stop), it will do so somewhere between the 0th and the 999th entry. Suppose it's on entry 300. Now, given we've chosen this key, for deciding the next key in the final list, our enumeration will continue with the remaining 700 elements and then will go on to the next 300 in the copy of the same enumeration. So, the 700+300 make exactly the 1000 in the hash table. This means that we will always consider each entry in the hash table once and only once. The other thing is that each time we attempt to find a key to go in the list that label could be found on entry 300 but also on entry 734 or something else, because the decide function actually depends on which previous keys have been chosen up to that point in the final list. So, each time we start fresh looking for an element for the final list in the hash table we start with a random element of the hash table.

Sorry if this is not very clear. It's hard to explain. =)

Thanks for all the comments.

Best, Surikator.


Hi yet again,

Sharing gasche's worries about mutable fields and enumerations in general and all the weird side-effects that can come from there, I decided to forget about off-the-shelf solutions using available hash tables libraries and wrote my stuff using plain lists. I also brought laziness to deal with avoiding generating random lists of which only part would be used (so there was useful lazy stuff to be used as you suggested, Niki).

I created the type

type 'a node_t =
   | ENil
   | ECons of 'a * 'a list * 'a t
and 'a t = ('a node_t) Lazy.t

for lazy random enumerations of lists. Each enumeration is either empty (ENil) or not (ECons) in which case it has three parts to it: (1) the element currently in focus, (2) the rest of available elements to enumerate, (3) another enumeration to continue this enumeration.

Then, a random enumeration of a list can be obtained using the create function

let rec create ls =
lazy(   match ls with
    | [] -> ENil
    | h::t -> let n = Random.int (List.length ls)
              in let newx,rest=remove ls n
          in ECons(newx,rest,create t))

where the auxiliary remove function has been defined to extract the nth element of a list and return a pair (x,ls) where x is the extracted element and ls is the new list without the extracted element. Just for completeness I add the code of the remove function here too.

let rec remove ls n =
let rec remove_ ls acc k n =
    match ls with
        | []        -> raise (Failure "remove")
        | h::t  -> if k=n
            then    h, List.rev_append acc t
            else remove_ t (h::acc) (k+1) n
in remove_ ls [] 0 n

We can now define very simple functions for generating the next state of the random enumeration and for getting the actual element in each state of the enumeration. Those are

exception End_of_enum
let next e =
match Lazy.force e with
    | ENil -> raise End_of_enum
    | ECons(x,ls,t) -> t
let rec get e =
match Lazy.force e with
    | ENil -> raise End_of_enum
    | ECons(x,ls,t) -> x

OK, up until now, I've simply enumerated lists randomly. If we want to enumerate a hash table instead, we can use

let rand_enum ht =
let ls = Hashtbl.fold (fun k v acc -> (k, v) :: acc) ht []
in create ls

to obtain a random enumeration of the pairs in the hash table and we can use next and get to obtain the (key,value) pairs. The fold but is just a way of getting all the (key,value) pairs of the hash table in a list (thanks Pascal for your answer in this question).

This ends the whole hash table enumeration thing. For the sake of completeness, I'm adding also the solution to the overall problem I was trying to solve, explained in "The Context" above. The problem, if you recall, is to randomly generate a list of (key,value) pairs from (1) a hash table, and (2) a decide function which can tell whether a (key,value) can be appended to some particular list of pairs. Since the whole generation process may never terminate, to ensure termination I thought it would make sense to have a third argument which is a function which tells whether we should stop the process or not (and which we should make sure will return true at some point for the whole process to terminate).

The function generate could be something like

let generate ht d stop =
let rec gen1 d fst e =
    if d (List.rev fst) (get e)
                then (get e)::fst
                else gen1 d fst (next e)
in let rec generate_ ht d stop acc =
            let e = rand_enum ht
            in  if stop acc
                        then acc
                        else    try generate_ ht d stop (gen1 d acc e)
                          with End_of_enum -> generate_ ht d stop (List.tl acc)
in generate_ ht d stop []

Thanks a lot to everyone who contributed with useful comments. This was really helpful.

All the best, Surikator.

  • If you may not need the whole list, then don't randomize the whole list; you should rewrite Fisher-Yates so it is lazy. – nlucaroni Oct 29 '10 at 18:45
  • @nlucaroni Thanks, that's a good suggestion. I've actually dealt with it slightly differently. I re-use the rest of the randomized list. – Surikator Oct 29 '10 at 18:55
  • @nlucaroni - I just wrote a lazy version of fisher-yates to explore that possibility! However I don't think it's possible to do that effectively with an Enum.t, you'd need to convert it to an array first. Since shuffle does that for you, I don't think the lazy approach makes much sense. – Niki Yoshiuchi Oct 29 '10 at 18:59
  • 1
    Have you considered another data structure? You can extend a map or set or hashtbl (as my link in another comment), to include a function that pulls a random element, and removes it, and returns a pair. Quite straight forward, and no transforming into arrays is necessary. – nlucaroni Oct 29 '10 at 20:36
  • @nlucaroni Yes, that's what I ended up doing. I created a lazy "random enumeration" type and appropriate functions to get random elements efficiently. Thanks for the suggestion. – Surikator Oct 30 '10 at 17:49

I have two suggestions. The first is to change your rand_enum function so it returns an Enum.t:

let rand_enum ht n =
BatRandom.init n;
let hte = BatHashtbl.enum ht
in Array.enum (BatRandom.shuffle hte)

which isn't terribly different (it's still computing a random enum for all 20k) but is closer to what you originally wanted.

Alternatively, you could always take the source code of HashTbl and recompile it with a rand_enum function. However this also probably won't be that different, as a HashTbl is implemented as an array and if you want to avoid bad duplicates you're probably going to end up using a shuffle.

  • Yes, Array.enum makes more sense. Thanks! – Surikator Oct 29 '10 at 17:39
  • 1
    You can extend the module; here is a map that I extended with some other properties (to get random elements from a map actually). You'd use it just the same as the Map module. nicholas.lucaroni.com/repo_pub/ocamlmaze/xMap.ml – nlucaroni Oct 29 '10 at 19:08
  • I did not know about include thanks! – Niki Yoshiuchi Oct 29 '10 at 19:30
  • 1
    ... yeah, and in ocaml 3.12+, you can use include for the signatures as well (that's why I don't have a signature for that file). And, you've made me fix that code, there was an error when I tried to compile that project a little while ago. heh, thanks! – nlucaroni Oct 29 '10 at 19:31

What is the density of potential next element ? What is the cost of your decide function ?

All your current solution have an O(n) cost. Fisher-Yates is O(n) (and it does not make much sense to try to adapt it for Enums, as it would require forcing the enumeration anyway), and Array.to_list alos is O(n).

If your decide function is fast enough and your density low enough, I think it may be simpler to just build a list/array of all eligible elements (calling decide on each element of the table), then randomly pick one of them.

If the density is high enough and decide costly, I think your first idea, picking keys at random and keeping a list of already-encountered keys. You will be able to pick the first eligible element encountered (optimal number of decide calls). This way to enumerate a sequence gets costly "in the end", when all elements have already been picked, but if your density is high you won't run into that case.

If you don't know, it may be interesting to start with the "high density" hypothesis, and change your mind once you've seen a given portion of the table, and still found nothing.

Finally: if you don't need to add/remove elements during the generation of your sequence, it would be interesting to convert your hashtable into an array once and forall (keeping another key -> array index table somewhere), as all such problems are simpler when the indexing is contiguous.

  • Thanks for the very useful comments. I don't know. I am studying an unknown search space. The decide function doesn't have high costs and I suspect that the density of the next potential element will be quite low. I've now edited the question again to include a different random hash table enumeration module. It deals away with the costs of passing an array to a list and only uses the Fisher-Yates algorithm once at the start, so in the long run we can consider its complexity O(1). Have a read and let me know if you have any comments. – Surikator Oct 29 '10 at 18:52

Your implementations )(second and third) are too complicated. I don't like mutable and I don't like Enum. Combining them both is the best way to shoot yourself in the foot with uncontrolled side-effects.

I also think your particular problem is too specific to be solved by a generic-looking "shuffle something and that's it" function. Trying to find such a domain-independent function which also solves your domain-specific problem is maybe why your successive implementation get uglier and more complex at each attempt.

Producing a random stream from a Hashtable is simple : BatHashtbl.enum |- BatRandom.shuffle |- BatArray.enum. The rest of your code should concern the use of the decide function.

  • I also didn't like mutable and Enum. I've now changed the implementation not to use them. I don't agree that the problem is too specific. The solution I propose above is for a general hash table and general decide function. Having this solution one can now plug in a particular hash table and a particular function and get a list of (key,value) from the hash table that has been obtained randomly. Thanks for the useful comments. – Surikator Oct 30 '10 at 17:52

I doubt that there is such function given the interface exposed by Hashtbl. Obvious approach like getting all the values into an array and doing lookups by Array.get a (Random.int (Array.length a)) looks fine to me.

  • Thanks for the reply. That solution has the problem of possibly repeating the element you extract with Array.get. If I've extracted one element and it didn't work, I don't want to extract it again (and this may happen if the Random.int happens to repeat). But yes, I agree that this can be done using without a specific Hashtbl function. – Surikator Oct 29 '10 at 14:48
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    @Surikator - instead of random choosing an element, you could shuffle the array (using the Fisher-Yates algorithm) and then go through the elements in order. – Niki Yoshiuchi Oct 29 '10 at 15:39
  • @Niki That's a good suggestion. I've edited the question to include code for that idea. Still something to be done regarding efficiency, though. – Surikator Oct 29 '10 at 16:27

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