I need a data structure that supports FAST insertion and deletion of (key, value) pairs, as well as "get random key", which does the same thing as random.choice(dict.keys()) for a dictionary. I've searched on the internet, and most people seem to be satisfied with the random.choice(dict.keys()) approach, despite it being linear time.

I'm aware that implementing this faster is possible:

  • I could use a resizing hash table. If I maintain that the ratio of keys to slots is between 1 and 2, then I can just choose random indices until I hit a non-empty slot. I only look at 1 to 2 keys, in expectation.
  • I can get these operations in guaranteed worst case O(log n) using an AVL tree, augmenting with rank.

Is there any easy way to get this in Python, though? It seems like there should be!

  • 1
    Here's an idea: keep another dict of the form {i: key}, where i is a counter. Then, to do a random lookup, call randint on this other dictionary. Correct me if I'm wrong, but this sounds like O(1). – Joel Cornett May 31 '12 at 20:55
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    Well, it's not obvious how to do insertion and deletion, from what you said. However, this does work, to an extent. Keep track of the maximum counter value, call it n. For insertions, we first try 2 (or 5, or any constant number of) random values between 1 and n. If they were both taken, use n and increment the max counter value. Otherwise, insert at the empty one. Neat! – WuTheFWasThat May 31 '12 at 21:37
  • I'm curious as to the intended use of this data structure. What's the use case? – Daenyth May 31 '12 at 22:42
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    Not easy to explain. 500 character version: I'm writing a compiler for a probabilistic programming language (see link), and inference requires a random walk over possible choices of randomness (see link). There is a complicated labeling system of execution points of a program, where randomness occurs. These labels are the keys in my dictionary. To do inference requires insertion, deletion, and "get random key" (in order use the proposal density in Metropolis-Hastings). – WuTheFWasThat May 31 '12 at 23:02

This may not specifically relevant to the specific use case listed above, but this is the question I get when searching for a way to nicely get a hold of "any" key in a dictionary.

If you don't need a truly random choice, but just need some arbitrary key, here are two simple options I've found:

key = next(iter(d))    # may be a little expensive, but presumably O(1)

The second is really useful only if you're happy to consume the key+value from the dictionary, and due to the mutation(s) will not be as algorithmically efficient:

key, value = d.popitem()     # may not be O(1) especially if next step
    d[key] = value
  • 1
    next(iter(d)) works on Python3 as well as Python2 (instead of d.iterkeys().next()) – kd88 Nov 11 '16 at 15:45
  • @kd88 Thanks! I updated my answer to incorporate that tip. – natevw Nov 14 '16 at 21:34

[edit: Completely rewritten, but keeping question here with comments intact.]

Below is the realization of a dictionary wrapper with O(1) get/insert/delete, and O(1) picking of a random element.

The main idea is that we want to have an O(1) but arbitrary map from range(len(mapping)) to the keys. This will let us get random.randrange(len(mapping)), and pass it through the mapping.

This is very difficult to implement until you realize that we can take advantage of the fact that the mapping can be arbitrary. The key idea to achieve a hard bound of O(1) time is this: whenever you delete an element, you swap it with the highest arbitrary-id element, and update any pointers.

class RandomChoiceDict(object):
    def __init__(self):
        self.mapping = {}  # wraps a dictionary
                           # e.g. {'a':'Alice', 'b':'Bob', 'c':'Carrie'}

        # the arbitrary mapping mentioned above
        self.idToKey = {}  # e.g. {0:'a', 1:'c' 2:'b'}, 
                           #      or {0:'b', 1:'a' 2:'c'}, etc.

        self.keyToId = {}  # needed to help delete elements

Get, set, and delete:

    def __getitem__(self, key):  # O(1)
        return self.mapping[key]

    def __setitem__(self, key, value):  # O(1)
        if key in self.mapping:
            self.mapping[key] = value
        else: # new item
            newId = len(self.mapping)

            self.mapping[key] = value

            # add it to the arbitrary bijection
            self.idToKey[newId] = key
            self.keyToId[key] = newId

    def __delitem__(self, key):  # O(1)
        del self.mapping[key]  # O(1) average case
                               # see http://wiki.python.org/moin/TimeComplexity

        emptyId = self.keyToId[key]
        largestId = len(self.mapping)  # about to be deleted
        largestIdKey = self.idToKey[largestId]  # going to store this in empty Id

        # swap deleted element with highest-id element in arbitrary map:
        self.idToKey[emptyId] = largestIdKey
        self.keyToId[largestIdKey] = emptyId

        del self.keyToId[key]
        del self.idToKey[largestId]

Picking a random (key,element):

    def randomItem(self):  # O(1)
        r = random.randrange(len(self.mapping))
        k = self.idToKey[r]
        return (k, self.mapping[k])
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    Keep a list of the keys, not a set. – Reinstate Monica May 31 '12 at 20:43
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    @BasicWolf: No, set.pop is not random. – Reinstate Monica May 31 '12 at 20:48
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    Well, it can't be "Fast, Good and Cheap" at the same time :) But anyway, my bad and thank you for explaining. – Zaur Nasibov May 31 '12 at 20:54
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    @WuTheFWasThat: The issue with making it a list in CPython is that it wouldn't then be able to do O(1) deletions. Generally it should be able to if the programming language is well implemented, if you are deleting only from the end or beginning of the list, but CPython does not claim to be able to do so in O(1) time. Though perhaps my source is just not being specific enough: wiki.python.org/moin/TimeComplexity Since CPython can append in O(1) time it can probably delete in O(1) time from the end, but the source did not say. – ninjagecko May 31 '12 at 22:22
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    @ninjagecko It seems like many of the above comments (as well as these last few) are useless and even misleading, since you edited the code drastically. Should we have them deleted then? I'm guessing we can't do it? – WuTheFWasThat May 31 '12 at 22:39

Here is a somewhat convoluted approach:

  • Assign an index to each key, storing it with the value in the dictionary.
  • Keep an integer representing the next index (let's call this next_index).
  • Keep a linked list of removed indices (gaps).
  • Keep a dictionary mapping the indices to keys.
  • When adding a key, check the use (and remove) the first index in the linked list as the index, or if the list is empty use and increment next_index. Then add the key, value, and index to the dictionary (dictionary[key] = (index, value)) and add the key to the index-to-key dictionary (indexdict[index] = key).
  • When removing a key, get the index from the dictionary, remove the key from the dictionary, remove the index from the index-to-key dictionary, and insert the index to the front of the linked list.
  • To get a random key, get a random integer using something like random.randrange(0, next_index). If the index is not in the key-to-index dictionary, re-try (this should be rare).

Here is an implementation:

import random

class RandomDict(object):
    def __init__(self): # O(1)
        self.dictionary = {}
        self.indexdict = {}
        self.next_index = 0
        self.removed_indices = None
        self.len = 0

    def __len__(self): # might as well include this
        return self.len

    def __getitem__(self, key): # O(1)
        return self.dictionary[key][1]

    def __setitem__(self, key, value): # O(1)
        if key in self.dictionary: # O(1)
            self.dictionary[key][1] = value # O(1)
        if self.removed_indices is None:
            index = self.next_index
            self.next_index += 1
            index = self.removed_indices[0]
            self.removed_indices = self.removed_indices[1]
        self.dictionary[key] = [index, value] # O(1)
        self.indexdict[index] = key # O(1)
        self.len += 1

    def __delitem__(self, key): # O(1)
        index = self.dictionary[key][0] # O(1)
        del self.dictionary[key] # O(1)
        del self.indexdict[index] # O(1)
        self.removed_indices = (index, self.removed_indices)
        self.len -= 1

    def random_key(self): # O(log(next_item/len))
        if self.len == 0: # which is usually close to O(1)
            raise KeyError
        while True:
            r = random.randrange(0, self.next_index)
            if r in self.indexdict:
                return self.indexdict[r]
  • Thanks! Yeah, this will work. Don't know why I didn't think of it. Hmm... it doesn't do well if you do a lot of deletes, so that next_index is much larger than the number of items. This can actually happen sometimes in my program. However, I can optimize so that this isn't an issue. – WuTheFWasThat May 31 '12 at 21:32
  • @WuTheFWasThat Yeah, I couldn't think of an easy way around that. At least when you add things after deleting, it reuses their indices. – Matt May 31 '12 at 21:41
  • I don't believe this will result in an O(1) random_key() function. For example, if you insert 1000000 elements and delete 1000000 elements, each call to random_key will result in a 1/1000000 chance of success despite having a handful of elements in the mapping. – ninjagecko May 31 '12 at 21:41
  • @ninjagecko You are right, we were just discussing that. (Although technically you are wrong, 1000000 - 1000000 = 0, so it will raise an exception right away. You probably meant delete 999999 elements.) – Matt May 31 '12 at 21:46
  • @ninjagecko - Yeah, I think Matt and I were both aware of this problem. Here is a solution which is no worse than hash-table resizing, but doesn't involve re-implementing dictionaries: Keep track of the number of things in the table. When it goes below next_index / 2, rebuild your whole indexing system with new_next_index = next_index/2, using indices 1, ... , new_next_index for the guys in the table – WuTheFWasThat May 31 '12 at 21:52

I had the same problem and wrote


I hope it helps you! It provides O(1) access to random keys, values or items.

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    Posting a link to external source is not advisable, because then can break in the future. i would suggest you to provide some explanation here and give reference. – YoungHobbit Sep 27 '15 at 15:55
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    That said, I think this is actually the best solution code-wise. It's clean and doesn't seem to have any major algorithmic drawbacks. There is a bug (fixed easily but in an un-merged PR) to watch out for. – zplizzi Dec 26 '19 at 15:57
  • As @zplizzi suggests, randomdict is the optimal solution. By compare to @ninjagecko's otherwise useful solution that internally maintains three (!) dictionaries, randomdict only internally maintains one dictionary and a list of 2-tuples. Yes, it's unfortunate that this answer effectively reduces to an HTTP 301 URL redirect – but such is the nature of the open-source code beast. Sometimes, the best implementation already exists as a black-box package. This is one of those times. – Cecil Curry Sep 9 '20 at 6:02
  • Actually... maybe not. randomdict deletions are O(n), as the underlying implementation deletes from an internal list. This is the classic space versus time tradeoff. Generally, we prefer consuming space to save time – which makes randomdict suboptimal for the general case. Nonetheless, randomdict space consumption does scale significantly better for larger dictionary sizes. </shrug> – Cecil Curry Sep 10 '20 at 2:01

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