# How can I optimize this Python code to generate all words with word-distance 1?

Profiling shows this is the slowest segment of my code for a little word game I wrote:

``````def distance(word1, word2):
difference = 0
for i in range(len(word1)):
if word1[i] != word2[i]:
difference += 1
return difference

def getchildren(word, wordlist):
return [ w for w in wordlist if distance(word, w) == 1 ]
``````

Notes:

• `distance()` is called over 5 million times, majority of which is from getchildren, which is supposed to get all words in the wordlist that differ from `word` by exactly 1 letter.
• wordlist is pre-filtered to only have words containing the same number of letters as `word` so it's guaranteed that `word1` and `word2` have the same number of chars.
• I'm fairly new to Python (started learning it 3 days ago) so comments on naming conventions or other style things also appreciated.
• for wordlist, take the 12dict word list using the "2+2lemma.txt" file

Results:

Thanks everyone, with combinations of different suggestions I got the program running twice as fast now (on top of the optimizations I did on my own before asking, so 4 times speed increase approx from my initial implementation)

I tested with 2 sets of inputs which I'll call A and B

Optimization1: iterate over indices of word1,2 ... from

``````for i in range(len(word1)):
if word1[i] != word2[i]:
difference += 1
return difference
``````

to iterate on letter-pairs using `zip(word1, word2)`

``````for x,y in zip (word1, word2):
if x != y:
difference += 1
return difference
``````

Got execution time from 11.92 to 9.18 for input A, and 79.30 to 74.59 for input B

Optimization2: Added a separate method for differs-by-one in addition to the distance-method (which I still needed elsewhere for the A* heuristics)

``````def is_neighbors(word1,word2):
different = False
for c1,c2 in zip(word1,word2):
if c1 != c2:
if different:
return False
different = True
return different
``````

Got execution time from 9.18 to 8.83 for input A, and 74.59 to 70.14 for input B

Optimization3: Big winner here was to use `izip` instead of `zip`

Got execution time from 8.83 to 5.02 for input A, and 70.14 to 41.69 for input B

I could probably do better writing it in a lower level language, but I'm happy with this for now. Thanks everyone!

Edit again: More results Using Mark's method of checking the case where the first letter doesn't match got it down from 5.02 -> 3.59 and 41.69 -> 29.82

Building on that and incorporating `izip` instead of `range`, I ended up with this:

``````def is_neighbors(word1,word2):
if word1 != word2:
return word1[1:] == word2[1:]
different = False
for x,y in izip(word1[1:],word2[1:]):
if x != y:
if different:
return False
different = True
return different
``````

Which squeezed a little bit more, bringing the times down from 3.59 -> 3.38 and 29.82 -> 27.88

Even more results!

Trying Sumudu's suggestion that I generate a list of all strings that are 1 letter off from "word" and then checking to see which ones were in the wordlist, instead of the is_neighbor function I ended up with this:

``````def one_letter_off_strings(word):
import string
dif_list = []
for i in xrange(len(word)):
dif_list.extend((word[:i] + l + word[i+1:] for l in string.ascii_lowercase if l != word[i]))
return dif_list

def getchildren(word, wordlist):
oneoff = one_letter_off_strings(word)
return ( w for w in oneoff if w in wordlist )
``````

Which ended up being slower (3.38 -> 3.74 and 27.88 -> 34.40) but it seemed promising. At first I thought the part I'd need to optimize was "one_letter_off_strings" but profiling showed otherwise and that the slow part was in fact

``````( w for w in oneoff if w in wordlist )
``````

I thought if there'd be any difference if I switched "oneoff" and "wordlist" and did the comparison the other way when it hit me that I was looking for the intersection of the 2 lists. I replace that with set-intersection on the letters:

``````return set(oneoff) & set(wordlist)
``````

Bam! 3.74 -> 0.23 and 34.40 -> 2.25

This is truely amazing, total speed difference from my original naive implementation: 23.79 -> 0.23 and 180.07 -> 2.25, so approx 80 to 100 times faster than the original implementation.

If anyone is interested, I made blog post describing the program and describing the optimizations made including one that isn't mentioned here (because it's in a different section of code).

The Great Debate:

Ok, me and Unknown are having a big debate which you can read in the comments of his answer. He claims that it would be faster using the original method (using is_neighbor instead of using the sets) if it was ported to C. I tried for 2 hours to get a C module I wrote to build and be linkable without much success after trying to follow this and this example, and it looks like the process is a little different in Windows? I don't know, but I gave up on that. Anyway, here's the full code of the program, and the text file come from the 12dict word list using the "2+2lemma.txt" file. Sorry if the code's a little messy, this was just something I hacked together. Also I forgot to strip out commas from the wordlist so that's actually a bug that you can leave in for the sake of the same comparison or fix it by adding a comma to the list of chars in cleanentries.

``````from itertools import izip
def unique(seq):
seen = {}
result = []
for item in seq:
if item in seen:
continue
seen[item] = 1
result.append(item)
return result
def cleanentries(li):
pass
return unique( [w.strip('[]') for w in li if w != "->"] )
def distance(word1, word2):
difference = 0
for x,y in izip (word1, word2):
if x != y:
difference += 1
return difference
def is_neighbors(word1,word2):
if word1 != word2:
return word1[1:] == word2[1:]
different = False
for x,y in izip(word1[1:],word2[1:]):
if x != y:
if different:
return False
different = True
return different
def one_letter_off_strings(word):
import string
dif_list = []
for i in xrange(len(word)):
dif_list.extend((word[:i] + l + word[i+1:] for l in string.ascii_lowercase if l != word[i]))
return dif_list

def getchildren(word, wordlist):
oneoff = one_letter_off_strings(word)
return set(oneoff) & set(wordlist)
def AStar(start, goal, wordlist):
import Queue
closedset = []
openset = [start]
pqueue = Queue.PriorityQueue(0)
g_score = {start:0}         #Distance from start along optimal path.
h_score = {start:distance(start, goal)}
f_score = {start:h_score[start]}
pqueue.put((f_score[start], start))
parent_dict = {}
while len(openset) > 0:
x = pqueue.get(False)
if x == goal:
return reconstruct_path(parent_dict,goal)
openset.remove(x)
closedset.append(x)
sortedOpen = [(f_score[w], w, g_score[w], h_score[w]) for w in openset]
sortedOpen.sort()
for y in getchildren(x, wordlist):
if y in closedset:
continue
temp_g_score = g_score[x] + 1
temp_is_better = False
appended = False
if (not y in openset):
openset.append(y)
appended = True
h_score[y] = distance(y, goal)
temp_is_better = True
elif temp_g_score < g_score[y] :
temp_is_better = True
else :
pass
if temp_is_better:
parent_dict[y] = x
g_score[y] = temp_g_score
f_score[y] = g_score[y] + h_score[y]
if appended :
pqueue.put((f_score[y], y))
return None

def reconstruct_path(parent_dict,node):
if node in parent_dict.keys():
p = reconstruct_path(parent_dict,parent_dict[node])
p.append(node)
return p
else:
return []

wordfile = open("2+2lemma.txt")
wordfile.close()
words = []
while True:
userentry = raw_input("Hello, enter the 2 words to play with separated by a space:\n ")
words = [w.lower() for w in userentry.split()]
if(len(words) == 2 and len(words) == len(words)):
break
print "You selected %s and %s as your words" % (words, words)
wordlist = [ w for w in wordlist if len(words) == len(w)]
print "Minimum number of steps is %s" % (len(answer))
else:
print "Good luck!"
else:
print "Sorry, there's no answer to yours"
reply = raw_input("Press enter to exit")
``````

I left the is_neighbors method in even though it's not used. This is the method that is proposed to be ported to C. To use it, just replace getchildren with this:

``````def getchildren(word, wordlist):
return ( w for w in wordlist if is_neighbors(word, w))
``````

As for getting it to work as a C module I didn't get that far, but this is what I came up with:

``````#include "Python.h"

static PyObject *
py_is_neighbor(PyObject *self, Pyobject *args)
{
int length;
const char *word1, *word2;
if (!PyArg_ParseTuple(args, "ss", &word1, &word2, &length))
return NULL;

int i;
int different = 0;
for (i =0; i < length; i++)
{
if (*(word1 + i) != *(word2 + i))
{
if (different)
{
return Py_BuildValue("i", different);
}
different = 1;
}
}
return Py_BuildValue("i", different);
}

PyMethodDef methods[] = {
{"isneighbor", py_is_neighbor, METH_VARARGS, "Returns whether words are neighbors"},
{NULL, NULL, 0, NULL}
};

PyMODINIT_FUNC
initIsNeighbor(void)
{
Py_InitModule("isneighbor", methods);
}
``````

I profiled this using:

python -m cProfile "Wordgame.py"

And the time recorded was the total time of the AStar method call. The fast input set was "verse poets" and the long input set was "poets verse". Timings will obviously vary between different machines, so if anyone does end up trying this give result comparison of the program as is, as well as with the C module.

• How should the distance be calculated if word2 is a prefix of word1? – Markus Jarderot Apr 25 '09 at 2:30
• Could I ask you to run the timings one more time with my latest function? I'm really curious to see how it compares on your actual data. – Mark Ransom Apr 25 '09 at 4:04
• take a look at `edits1(word)` function on norvig.com/spell-correct.html – jfs Feb 4 '11 at 7:44
• Must we do this in Python 2.x (izip doesn't exist in 3.x)? It's far more reusable to do it in 3.x; also optimizations and trie library implementations will differ. – smci Oct 14 '16 at 21:47

If your wordlist is very long, might it be more efficient to generate all possible 1-letter-differences from 'word', then check which ones are in the list? I don't know any Python but there should be a suitable data structure for the wordlist allowing for log-time lookups.

I suggest this because if your words are reasonable lengths (~10 letters), then you'll only be looking for 250 potential words, which is probably faster if your wordlist is larger than a few hundred words.

• Wow.... I think I'm going to have to accept this... you just gave it a 1000% speed boost... Well, with slight modification of converting the lists to sets and doing an intersection instead of checking what's in the list, but the general idea got me there. I'm glad I tried it out, I was skeptical at first because I thought that generating the lists would take a long time and was worried about figuring out how to optimize that part. Turns out creating that was really fast and the checking if each one was in the list that was long, and changing that to using sets turbo charged it. – Davy8 Apr 25 '09 at 14:06
• Optimization has always been first and foremost about selecting the proper algorithm, then fine-tuning once you have it. Congrats for thinking out of the box. – Mark Ransom Apr 26 '09 at 3:55
• Interesting find, but I think this is more of a Python specific optimization (that sets are faster than array access). Think about the cost of searching among 25L (L for letters) as opposed to matching L/2 (assuming you will find 2+ differences by half the word). In a close to the metal language like C, I believe you will find that the set search will be less optimal until log(25) > L/2 - log(L). I graphed the function, and this is true for L > 17 letters long. imgur.com/27AUC.png – Unknown Apr 27 '09 at 8:03
• I kind of disappeared from SO for a while so I didn't see this till now. As I noted in my answer, I don't know Python but you should be using a wordlist that supports log-time lookups, which is apparently set (like in C++). I disagree with unknown's analysis because he is not considering the number of words (W) in the wordlist. With my method, the worst case is 25L * log(W), but checking each word in the wordlist doesn't take advantage of the set structure, and takes W * L/2 (using his approximation). So if the word list is long enough my method is faster (as I noted at the start). – Sumudu Fernando Aug 27 '09 at 16:11
• Just realised that worst-case for mine needs another factor of L due to the string comparison that happens during the set lookup. Davy8 has mentioned the number of words is around 4500 while the length of each word is around 5, so this is still okay. Unknown: If I were doing this in C++, I would still do it my way with std::set. – Sumudu Fernando Aug 27 '09 at 16:22

Your function `distance` is calculating the total distance, when you really only care about distance=1. The majority of cases you'll know it's >1 within a few characters, so you could return early and save a lot of time.

Beyond that, there might be a better algorithm, but I can't think of it.

Edit: Another idea.

You can make 2 cases, depending on whether the first character matches. If it doesn't match, the rest of the word has to match exactly, and you can test for that in one shot. Otherwise, do it similarly to what you were doing. You could even do it recursively, but I don't think that would be faster.

``````def DifferentByOne(word1, word2):
if word1 != word2:
return word1[1:] == word2[1:]
same = True
for i in range(1, len(word1)):
if word1[i] != word2[i]:
if same:
same = False
else:
return False
return not same
``````

Edit 2: I've deleted the check to see if the strings are the same length, since you say it's redundant. Running Ryan's tests on my own code and on the is_neighbors function provided by MizardX, I get the following:

• Original distance(): 3.7 seconds
• My DifferentByOne(): 1.1 seconds
• MizardX's is_neighbors(): 3.7 seconds

Edit 3: (Probably getting into community wiki territory here, but...)

Trying your final definition of is_neighbors() with izip instead of zip: 2.9 seconds.

``````def DifferentByOne(word1, word2):
if word1 != word2:
return word1[1:] == word2[1:]
different = False
for i in range(1, len(word1)):
if word1[i] != word2[i]:
if different:
return False
different = True
return different
``````
• if word1 != word2: return word1[1:] == word2[1:] This is likely to make it slower because slicing an immutable string creates a new copy of the string in memory. – Unknown Apr 25 '09 at 3:01
• That seems slower than the original code, with a really basic benchmark.. Using the timeit module, distance("abc", "abd") took 4.03 seconds, DifferenceByOne("abc", "abd") took 5.02 – dbr Apr 25 '09 at 3:08
• Is indexing each character also a slicing operation? That would probably be slow, too. – Mark Ransom Apr 25 '09 at 3:10
• ..those benchmarks were repeating the code 1 million times, using import timeit; t=timeit.Timer("code").timeit() on Python 2.5.1 – dbr Apr 25 '09 at 3:10
• Seeing all the responses with zip or izip, I see I still have some learning to do. I'm still thinking in C/C++. – Mark Ransom Apr 25 '09 at 3:11
``````from itertools import izip

def is_neighbors(word1,word2):
different = False
for c1,c2 in izip(word1,word2):
if c1 != c2:
if different:
return False
different = True
return different
``````

Or maybe in-lining the `izip` code:

``````def is_neighbors(word1,word2):
different = False
next1 = iter(word1).next
next2 = iter(word2).next
try:
while 1:
if next1() != next2():
if different:
return False
different = True
except StopIteration:
pass
return different
``````

And a rewritten `getchildren`:

``````def iterchildren(word, wordlist):
return ( w for w in wordlist if is_neighbors(word, w) )
``````

People are mainly going about this by trying to write a quicker function, but there might be another way..

"distance" is called over 5 million times

Why is this? Perhaps a better way to optimise is to try and reduce the number of calls to `distance`, rather than shaving milliseconds of `distance's` execution time. It's impossible to tell without seeing the full script, but optimising a specific function is generally unnecessary.

If that is impossible, perhaps you could write it as a C module?

• Excellent point. The data could certainly be organized in a way that would eliminate a number of the checks. – Dan Olson Apr 25 '09 at 3:45
• I thought about it, but really 90-95% of the calls are from the getchildren function shown above, so unless there's a way to have that call distance fewer times, I'm not sure. – Davy8 Apr 25 '09 at 4:47
• lol, well I guess I did end up eliminating the call to distance all together – Davy8 Apr 25 '09 at 14:25

How often is the distance function called with the same arguments? A simple to implement optimization would be to use memoization.

You could probably also create some sort of dictionary with frozensets of letters and lists of words that differ by one and look up values in that. This datastructure could either be stored and loaded through pickle or generated from scratch at startup.

Short circuiting the evaluation will only give you gains if the words you are using are very long, since the hamming distance algorithm you're using is basically O(n) where n is the word length.

I did some experiments with timeit for some alternative approaches that may be illustrative.

# Timeit Results

``````d = """\
def distance(word1, word2):
difference = 0
for i in range(len(word1)):
if word1[i] != word2[i]:
difference += 1
return difference
"""
t1 = timeit.Timer('distance("hello", "belko")', d)
print t1.timeit() # prints 6.502113536776391
``````

## One Liner

``````d = """\
from itertools import izip
def hamdist(s1, s2):
return sum(ch1 != ch2 for ch1, ch2 in izip(s1,s2))
"""
t2 = timeit.Timer('hamdist("hello", "belko")', d)
print t2.timeit() # prints 10.985101179
``````

## Shortcut Evaluation

``````d = """\
def distance_is_one(word1, word2):
diff = 0
for i in xrange(len(word1)):
if word1[i] != word2[i]:
diff += 1
if diff > 1:
return False
return diff == 1
"""
t3 = timeit.Timer('hamdist("hello", "belko")', d)
print t2.timeit() # prints 6.63337
``````
• In a question about optimisation, you're the only person (so far) to provide any kind of benchmark.. :/ – dbr Apr 25 '09 at 3:28
• I could look into the memorization stuff. It's more involved than I'd like to try for tonight, maybe tomorrow, but +1 for it anyway since it seems like it could help. – Davy8 Apr 25 '09 at 3:31
• It's spelled "memoization" there's no "r" in memoize. – S.Lott Apr 25 '09 at 11:43

Well you can start by having your loop break if the difference is 2 or more.

Also you can change

``````for i in range(len(word1)):
``````

to

``````for i in xrange(len(word1)):
``````

Because xrange generates sequences on demand instead of generating the whole range of numbers at once.

You can also try comparing word lengths which would be quicker. Also note that your code doesn't work if word1 is greater than word2

There's not much else you can do algorithmically after that, which is to say you'll probably find more of a speedup by porting that section to C.

Edit 2

Attempting to explain my analysis of Sumudu's algorithm compared to verifying differences char by char.

When you have a word of length L, the number of "differs-by-one" words you will generate will be 25L. We know from implementations of sets on modern computers, that the search speed is approximately log(n) base 2, where n is the number of elements to search for.

Seeing that most of the 5 million words you test against is not in the set, most of the time, you will be traversing the entire set, which means that it really becomes log(25L) instead of only log(25L)/2. (and this is assuming best case scenario for sets that comparing string by string is equivalent to comparing char by char)

Now we take a look at the time complexity for determining a "differs-by-one". If we assume that you have to check the entire word, then the number of operations per word becomes L. We know that most words differ by 2 very quickly. And knowing that most prefixes take up a small portion of the word, we can logically assume that you will break most of the time by L/2, or half the word (and this is a conservative estimate).

So now we plot the time complexities of the two searches, L/2 and log(25L), and keeping in mind that this is even considering string matching the same speed as char matching (highly in favor of sets). You have the equation log(25*L) > L/2, which can be simplified down to log(25) > L/2 - log(L). As you can see from the graph, it should be quicker to use the char matching algorithm until you reach very large numbers of L. Also, I don't know if you're counting breaking on difference of 2 or more in your optimization, but from Mark's answer I already break on a difference of 2 or more, and actually, if the difference in the first letter, it breaks after the first letter, and even in spite of all those optimizations, changing to using sets just blew them out of the water. I'm interested in trying your idea though

I was the first person in this question to suggest breaking on a difference of 2 or more. The thing is, that Mark's idea of string slicing (if word1 != word2: return word1[1:] == word2[1:]) is simply putting what we are doing into C. How do you think word1[1:] == word2[1:] is calculated? The same way that we are doing.

I read your explanation a few times but I didn't quite follow it, would you mind explaining it a little more indepth? Also I'm not terribly familiar with C and I've been working in high-level languages for the past few years (closest has been learning C++ in high school 6 years ago

As for producing the C code, I am a bit busy. I am sure you will be able to do it since you have written in C before. You could also try C#, which probably has similar performance characteristics.

More Explanation

Here is a more indepth explanation to Davy8

``````def getchildren(word, wordlist):
oneoff = one_letter_off_strings(word)
return set(oneoff) & set(wordlist)
``````

Your one_letter_off_strings function will create a set of 25L strings(where L is the number of letters).

Creating a set from the wordlist will create a set of D strings (where D is the length of your dictionary). By creating an intersection from this, you MUST iterate over each oneoff and see if it exists in wordlist.

The time complexity for this operation is detailed above. This operation is less efficient than comparing the word you want with each word in wordlist. Sumudu's method is an optimization in C rather than in algorithm.

More Explanation 2

There's only 4500 total words (because the wordlist is pre-filtered for 5 letter words before even being passed to the algorithm), being intersected with 125 one-letter-off words. It seemed that you were saying intersection is log(smaller) or in otherwords log(125, 2). Compare this to again assuming what you said, where comparing a word breaks in L/2 letters, I'll round this down to 2, even though for a 5 letter word it's more likely to be 3. This comparison is done 4500 times, so 9000. log(125,2) is about 6.9, and log(4500,2) is about 12. Lemme know if I misinterpreted your numbers.

To create the intersection of 125 one-letter-off words with a dictionary of 4500, you need to make 125 * 4500 comparisons. This is not log(125,2). It is at best 125 * log(4500, 2) assuming that the dictionary is presorted. There is no magic shortcut to sets. You are also doing a string by string instead of char by char comparison here.

• Won't "i in word1" return the characters, rather than the indexes? – Mark Ransom Apr 25 '09 at 2:32
• Yes, I consider it more pythonic to iterate over a string that way instead of doing range(len(string)). – Unknown Apr 25 '09 at 2:33
• Hmm, for the first point you're right, although I'd have to rename the function. As for iterating the string instead of the indexes, how will I compare whether that letter in word1 matches the corresponding letter in word2? – Davy8 Apr 25 '09 at 2:37
• I suppose you have a point there: You could do for i,c in enumerate(word1): c != word2[i] that might look a bit clunky but then I would suggest that you use "for i in xrange(len(word1))" because xrange generates numbers on demand instead of a list that takes up memory. – Unknown Apr 25 '09 at 2:41
• I read your explanation a few times but I didn't quite follow it, would you mind explaining it a little more indepth? Also I'm not terribly familiar with C and I've been working in high-level languages for the past few years (closest has been learning C++ in high school 6 years ago), so if you could provide me with a code sample I could try it out and let you know the results. That being said I don't have any idea how sets are implemented under the hood in Python but they seem to be super optimized, and I'd be surprised if a not too complicated C module could do better. But gotta profile. – Davy8 Apr 27 '09 at 15:26

For such a simple function that has such a large performance implication, I would probably make a C library and call it using ctypes. One of reddit's founders claims they made the website 2x as fast using this technique.

You can also use psyco on this function, but beware that it can eat up a lot of memory.

I don't know if it will significantly affect your speed, but you could start by turning the list comprehension into a generator expression. It's still iterable so it shouldn't be much different in usage:

``````def getchildren(word, wordlist):
return [ w for w in wordlist if distance(word, w) == 1 ]
``````

to

``````def getchildren(word, wordlist):
return ( w for w in wordlist if distance(word, w) == 1 )
``````

The main problem would be that a list comprehension would construct itself in memory and take up quite a bit of space, whereas the generator will create your list on the fly so there is no need to store the whole thing.

Also, following on unknown's answer, this may be a more "pythonic" way of writing distance():

``````def distance(word1, word2):
difference = 0
for x,y in zip (word1, word2):
if x == y:
difference += 1
return difference
``````

But it's confusing what's intended when len (word1) != len (word2), in the case of zip it will only return as many characters as the shortest word. (Which could turn out to be an optimization...)

Try this:

``````def distance(word1, word2):
return sum([not c1 == c2 for c1, c2 in zip(word1,word2)])
``````

Also, do you have a link to your game? I like being destroyed by word games

• Not yet, but I could post it up somewhere. The code probably all fits on one printed page so it's fairly simple – Davy8 Apr 25 '09 at 2:51
• Looks like this is actually slightly slower, but it is shorter – Davy8 Apr 25 '09 at 2:55
• LOL - I'm a lot of help. Try it again with izip instead of zip, use tuple syntax instead of list, hopefully it improves. – user44484 Apr 25 '09 at 2:59

First thing to occur to me:

``````from operator import ne

def distance(word1, word2):
return sum(map(ne, word1, word2))
``````

which has a decent chance of going faster than other functions people have posted, because it has no interpreted loops, just calls to Python primitives. And it's short enough that you could reasonably inline it into the caller.

For your higher-level problem, I'd look into the data structures developed for similarity search in metric spaces, e.g. this paper or this book, neither of which I've read (they came up in a search for a paper I have read but can't remember).

for this snippet:

``````for x,y in zip (word1, word2):
if x != y:
difference += 1
return difference
``````

i'd use this one:

``````return sum(1 for i in xrange(len(word1)) if word1[i] == word2[i])
``````

the same pattern would follow all around the provided code...

Everyone else focused just on explicit distance-calculation without doing anything about constructing the distance-1 candidates. You can improve by using a well-known data-structure called a Trie to merge the implicit distance-calculation with the task of generating all distance-1 neighbor words. A Trie is a linked-list where each node stands for a letter, and the 'next' field is a dict with up to 26 entries, pointing to the next node.

Here's the pseudocode: walk the Trie iteratively for your given word; at each node add all distance-0 and distance-1 neighbors to the results; keep a counter of distance and decrement it. You don't need recursion, just a lookup function which takes an extra distance_so_far integer argument.

A minor tradeoff of extra speed for O(N) space increase can be gotten by building separate Tries for length-3, length-4, length-5 etc. words.