# Given a string of a million numbers, return all repeating 3 digit numbers

I had an interview with a hedge fund company in New York a few months ago and unfortunately, I did not get the internship offer as a data/software engineer. (They also asked the solution to be in Python.)

I pretty much screwed up on the first interview problem...

Question: Given a string of a million numbers (Pi for example), write a function/program that returns all repeating 3 digit numbers and number of repetition greater than 1

For example: if the string was: `123412345123456` then the function/program would return:

``````123 - 3 times
234 - 3 times
345 - 2 times
``````

They did not give me the solution after I failed the interview, but they did tell me that the time complexity for the solution was constant of 1000 since all the possible outcomes are between:

000 --> 999

Now that I'm thinking about it, I don't think it's possible to come up with a constant time algorithm. Is it?

• If they think the solution is a constant of 1000, then that makes me think that they would have built all the three-digit numbers, and then regex searched for them. It's very common for people to think that operations they didn't actually write/see are "free". I'm pretty sure this would be linear to the length of the string. Nov 30 '17 at 19:41
• Nitpickingly, if the input size is a constant, every algorithm is constant time ;-) Nov 30 '17 at 21:57
• a constant of 1000 what? (additions? elephants?) Nov 30 '17 at 22:28
• Well, if the string length is constant (1M) and the substring/number length is constant (3), then technically every solution is constant time… Dec 1 '17 at 1:55
• `They did not give me the solution after I failed the interview, but they did tell me that the time complexity for the solution was constant of 1000 since all the possible outcomes are between: 000 --> 999` This was likely the actual test. To see if you could prove to them why this is not possible and to show them the correct minimum time complexity. Dec 1 '17 at 15:31

You got off lightly, you probably don't want to be working for a hedge fund where the quants don't understand basic algorithms :-)

There is no way to process an arbitrarily-sized data structure in `O(1)` if, as in this case, you need to visit every element at least once. The best you can hope for is `O(n)` in this case, where `n` is the length of the string.

Although, as an aside, a nominal `O(n)` algorithm will be `O(1)` for a fixed input size so, technically, they may have been correct here. However, that's not usually how people use complexity analysis.

It appears to me you could have impressed them in a number of ways.

First, by informing them that it's not possible to do it in `O(1)`, unless you use the "suspect" reasoning given above.

Second, by showing your elite skills by providing Pythonic code such as:

``````inpStr = '123412345123456'

# O(1) array creation.
freq =  * 1000

# O(n) string processing.
for val in [int(inpStr[pos:pos+3]) for pos in range(len(inpStr) - 2)]:
freq[val] += 1

# O(1) output of relevant array values.
print ([(num, freq[num]) for num in range(1000) if freq[num] > 1])
``````

This outputs:

``````[(123, 3), (234, 3), (345, 2)]
``````

though you could, of course, modify the output format to anything you desire.

And, finally, by telling them there's almost certainly no problem with an `O(n)` solution, since the code above delivers results for a one-million-digit string in well under half a second. It seems to scale quite linearly as well, since a 10,000,000-character string takes 3.5 seconds and a 100,000,000-character one takes 36 seconds.

And, if they need better than that, there are ways to parallelise this sort of stuff that can greatly speed it up.

Not within a single Python interpreter of course, due to the GIL, but you could split the string into something like (overlap indicated by `vv` is required to allow proper processing of the boundary areas):

``````    vv
123412  vv
123451
5123456
``````

You can farm these out to separate workers and combine the results afterwards.

The splitting of input and combining of output are likely to swamp any saving with small strings (and possibly even million-digit strings) but, for much larger data sets, it may well make a difference. My usual mantra of "measure, don't guess" applies here, of course.

This mantra also applies to other possibilities, such as bypassing Python altogether and using a different language which may be faster.

For example, the following C code, running on the same hardware as the earlier Python code, handles a hundred million digits in 0.6 seconds, roughly the same amount of time as the Python code processed one million. In other words, much faster:

``````#include <stdio.h>
#include <string.h>

int main(void) {
static char inpStr[100000000+1];
static int freq;

// Set up test data.

memset(inpStr, '1', sizeof(inpStr));
inpStr[sizeof(inpStr)-1] = '\0';

// Need at least three digits to do anything useful.

if (strlen(inpStr) <= 2) return 0;

// Get initial feed from first two digits, process others.

int val = (inpStr - '0') * 10 + inpStr - '0';
char *inpPtr = &(inpStr);
while (*inpPtr != '\0') {

val = (val % 100) * 10 + *inpPtr++ - '0';
freq[val]++;
}

// Output (relevant part of) table.

for (int i = 0; i < 1000; ++i)
if (freq[i] > 1)
printf("%3d -> %d\n", i, freq[i]);

return 0;
}
``````
• This "fixed input size" really sounds like a bad joke either the interviewer or the interviewee didn't get. Every algorithm becomes `O(1)` is `n` is fixed or bounded. Dec 1 '17 at 13:11
• If they need better than that, maybe they shouldn't be using Python, at least for the specific algorithm. Dec 1 '17 at 13:28
• @ezzzCash Because there may be overlap at the points where the string is being "broken up" when trying a parallel approach. Since you're looking for 3-digit groups, -2 allows the check on both parallel groupings to not miss a potentially valid match. Dec 1 '17 at 22:32
• @ezzzCash It's not a lack of parallel programming knowledge. Consider a string of length `N`. If you break it into two parts at position `N/2`, you still need to account for the fact that you could miss a valid 3-digit match at the "border", at the end of `string1` and the beginning of `string2`. Thus, you need to check matches between `string1[N/2-2]` and `string2` (using a zero-based index), etc. That's the idea. Dec 2 '17 at 3:28
• With longer digit-sequences, there'd be something to gain from optimizing the conversion to integer with a sliding window that lets you drop the highest digit and add a new digit. (Python overhead would probably kill this, so it would only apply to C or other low-level implementations). `val -= 100 * (d[i]-'0');` to drop the leading digit. `val = 10*val + d[i+2]-'0'` to accumulate a new least-significant digit (normal string->integer parsing). `val % 100` is possibly non-horrible, but only if `100` is a compile-time constant so it doesn't use a real HW divide. Dec 2 '17 at 10:09

Constant time isn't possible. All 1 million digits need to be looked at at least once, so that is a time complexity of O(n), where n = 1 million in this case.

For a simple O(n) solution, create an array of size 1000 that represents the number of occurrences of each possible 3 digit number. Advance 1 digit at a time, first index == 0, last index == 999997, and increment array[3 digit number] to create a histogram (count of occurrences for each possible 3 digit number). Then output the content of the array with counts > 1.

• @ezzzCash - yes a dictionary would work, but it's not needed. All possible "keys" are known in advance, limited to the range 0 to 999. The difference in overhead would be the time it takes to do a key based access using 3 character strings as keys, versus the time it takes to convert a 3 digit string to an index and then using the index to access the array. Nov 30 '17 at 20:14
• If you want numeric tricks, you could also decide to go BCD and store the three digits in 12 bits. And decode ASCII digits by masking the low 4 bits. But that `x-'0'` pattern is not valid in Python, it's a C-ism (where characters are integers). Nov 30 '17 at 20:32
• @LorenPechtel: Dictionary lookups in Python are really fast. Granted, array access is even faster, so if we were dealing with integers from the beginning, you'd be right. However, in this case, we have 3-length strings, which we first have to convert to integers if we want to use them with arrays. It turns out that contrary to what one might first expect, the dictionary lookup is actually faster than the integer conversion + array access. The array solution is in fact 50% slower in this case. Dec 1 '17 at 10:44
• I guess one could argue that if the input number has always exactly 1 million digits, than that algorithm is O(1), with a constant factor of 1 million. Dec 1 '17 at 14:57
• @AleksiTorhamo - If the goal is to compare relative speeds of implementations for an algorithm, I would prefer a traditional language like C or C++, since Python is significantly slower and seems to have overheads unique to Python compared to other languages. Dec 1 '17 at 16:16

A million is small for the answer I give below. Expecting only that you have to be able to run the solution in the interview, without a pause, then The following works in less than two seconds and gives the required result:

``````from collections import Counter

def triple_counter(s):
c = Counter(s[n-3: n] for n in range(3, len(s)))
for tri, n in c.most_common():
if n > 1:
print('%s - %i times.' % (tri, n))
else:
break

if __name__ == '__main__':
import random

s = ''.join(random.choice('0123456789') for _ in range(1_000_000))
triple_counter(s)
``````

Hopefully the interviewer would be looking for use of the standard libraries collections.Counter class.

# Parallel execution version

I wrote a blog post on this with more explanation.

• It works fine and seems to be the fastest, non numpy solution. Dec 1 '17 at 13:53
• @EricDuminil, I don't think you should worry about having the fastet timings here, when most solutions given won't delay you much. Far better to show that you have a good grasp of the Python standard library and can write maintainable code in an interview situation I would think. (Unless the interviewer stressed the time criticality whereupon you should ask for actual timings before assessing what comes next). Dec 1 '17 at 14:19
• We agree 100%. Though I'm not sure any answer is relevant at all if the interviewer really thinks it's possible to do in `O(1)`. Dec 1 '17 at 14:34
• If the interviewer stressed it was time critical, then, after profiling to confirm this is the limit, it may be time to write a C module to address this bottleneck. I have a script that saw an 84x improvement over python code after we switched to using a c module. Dec 1 '17 at 23:13
• Hi @TemporalWolf, I read what you said then thought that another, faster, and scaleable solution might be to change it to a parallel algorithm so it could be run on many processes on a compute farm/cloud. You have to split the string into n sections; overlapping the last 3 chars of each section with its next section. Each section can then be scanned for triples independently, the triples summed, and the three char triple at the end of all but the last section subtracted out as it would have been double counted. I have the code, and will probably turn it into a blog post... Dec 3 '17 at 21:22

The simple O(n) solution would be to count each 3-digit number:

``````for nr in range(1000):
cnt = text.count('%03d' % nr)
if cnt > 1:
print '%03d is found %d times' % (nr, cnt)
``````

This would search through all 1 million digits 1000 times.

Traversing the digits only once:

``````counts =  * 1000
for idx in range(len(text)-2):
counts[int(text[idx:idx+3])] += 1

for nr, cnt in enumerate(counts):
if cnt > 1:
print '%03d is found %d times' % (nr, cnt)
``````

Timing shows that iterating only once over the index is twice as fast as using `count`.

• Is there a black friday discount on `text.count()`? Nov 30 '17 at 19:57
• @EricDuminil You do have a good point but, since `text.count` is done in a high-speed compiled language (e.g. C) as opposed to slow python-level interpreted looping, yes there is a discount. Nov 30 '17 at 20:02
• It's very inefficient to count each number separately but it's a constant time, thus still O(n). Nov 30 '17 at 23:55
• The option you proposed that uses `count` is incorrect, since it won't count overlapping patterns. Note that `'111'.count('11') == 1` when we would expect it to be `2`. Dec 1 '17 at 0:50
• Also, your "simple `O(n)` solution" is actually `O(10**d * n)` with `d` the number of searched digits and `n` the total length of the string. The second one is `O(n)` time and `O(10**d + n)` space. Dec 1 '17 at 13:07

Here is a NumPy implementation of the "consensus" O(n) algorithm: walk through all triplets and bin as you go. The binning is done by upon encountering say "385", adding one to bin[3, 8, 5] which is an O(1) operation. Bins are arranged in a `10x10x10` cube. As the binning is fully vectorized there is no loop in the code.

``````def setup_data(n):
import random
digits = "0123456789"
return dict(text = ''.join(random.choice(digits) for i in range(n)))

def f_np(text):
# Get the data into NumPy
import numpy as np
a = np.frombuffer(bytes(text, 'utf8'), dtype=np.uint8) - ord('0')
# Rolling triplets
a3 = np.lib.stride_tricks.as_strided(a, (3, a.size-2), 2*a.strides)

bins = np.zeros((10, 10, 10), dtype=int)
# Next line performs O(n) binning
# Filtering is left as an exercise
return bins.ravel()

def f_py(text):
counts =  * 1000
for idx in range(len(text)-2):
counts[int(text[idx:idx+3])] += 1
return counts

import numpy as np
import types
from timeit import timeit
for n in (10, 1000, 1000000):
data = setup_data(n)
ref = f_np(**data)
print(f'n = {n}')
for name, func in list(globals().items()):
if not name.startswith('f_') or not isinstance(func, types.FunctionType):
continue
try:
assert np.all(ref == func(**data))
print("{:16s}{:16.8f} ms".format(name[2:], timeit(
'f(**data)', globals={'f':func, 'data':data}, number=10)*100))
except:
print("{:16s} apparently crashed".format(name[2:]))
``````

Unsurprisingly, NumPy is a bit faster than @Daniel's pure Python solution on large data sets. Sample output:

``````# n = 10
# np                    0.03481400 ms
# py                    0.00669330 ms
# n = 1000
# np                    0.11215360 ms
# py                    0.34836530 ms
# n = 1000000
# np                   82.46765980 ms
# py                  360.51235450 ms
``````
• Probably significantly faster to flatten the digit string instead of having nested bins, unless NumPy ends up implementing it as a 3D matrix with efficient indexing. Which version of @Daniel's did you time against; the one that runs a string search for each integer, or the one with a histogram? Dec 2 '17 at 9:50
• @PeterCordes I doubt it. `ndarray`s, the core numpy type, are all about efficient storage, manipulation and indexing of multidimensional arrays of numbers. Sometimes you can shave off a few % by flattening, but in this case doing the 100 x + 10 x + x by hand won't gain you much. I used the one @Daniel said was faster, you can check the benchmark code yourself. Dec 2 '17 at 13:35
• I don't really know NumPy (or Python in general; mostly I do C and assembly performance tuning for x86), but I think you have a single 3D array, right? I was thinking from your English text (which apparently I didn't even read carefully) that you had actual nested Python objects and were indexing them separately. But that's not the case, so nvm my first comment. Dec 2 '17 at 13:54
• I think the pure Python version you used is pretty much the same histogram implementation that the even higher voted answers used, but if different ways of writing it in Python affect the speed much. Dec 2 '17 at 13:57

I would solve the problem as follows:

``````def find_numbers(str_num):
final_dict = {}
buffer = {}
for idx in range(len(str_num) - 3):
num = int(str_num[idx:idx + 3])
if num not in buffer:
buffer[num] = 0
buffer[num] += 1
if buffer[num] > 1:
final_dict[num] = buffer[num]
return final_dict
``````

Applied to your example string, this yields:

``````>>> find_numbers("123412345123456")
{345: 2, 234: 3, 123: 3}
``````

This solution runs in O(n) for n being the length of the provided string, and is, I guess, the best you can get.

• You could simply use a `Counter`. You don't need a `final_dict`, and you don't have to update it at each iteration. Nov 30 '17 at 20:28

As per my understanding, you cannot have the solution in a constant time. It will take at least one pass over the million digit number (assuming its a string). You can have a 3-digit rolling iteration over the digits of the million length number and increase the value of hash key by 1 if it already exists or create a new hash key (initialized by value 1) if it doesn't exists already in the dictionary.

The code will look something like this:

``````def calc_repeating_digits(number):

hash = {}

for i in range(len(str(number))-2):

current_three_digits = number[i:i+3]
if current_three_digits in hash.keys():
hash[current_three_digits] += 1

else:
hash[current_three_digits] = 1

return hash
``````

You can filter down to the keys which have item value greater than 1.

As mentioned in another answer, you cannot do this algorithm in constant time, because you must look at at least n digits. Linear time is the fastest you can get.

However, the algorithm can be done in O(1) space. You only need to store the counts of each 3 digit number, so you need an array of 1000 entries. You can then stream the number in.

My guess is that either the interviewer misspoke when they gave you the solution, or you misheard "constant time" when they said "constant space."

• As others have pointed out, the histogram approach is `O(10**d)` extra space, where `d` is the number of decimal digits you're looking for. Dec 2 '17 at 9:56
• Dictionary approach would be O (min (10^d, n)) for n digits. For example if you have n = 10^9 digits and want to find the rare 15 digit sequences that occur more than once. Dec 2 '17 at 14:57

``````from timeit import timeit
from collections import Counter
import types
import random

def setup_data(n):
digits = "0123456789"
return dict(text = ''.join(random.choice(digits) for i in range(n)))

def f_counter(text):
c = Counter()
for i in range(len(text)-2):
ss = text[i:i+3]
c.update([ss])
return (i for i in c.items() if i > 1)

def f_dict(text):
d = {}
for i in range(len(text)-2):
ss = text[i:i+3]
if ss not in d:
d[ss] = 0
d[ss] += 1
return ((i, d[i]) for i in d if d[i] > 1)

def f_array(text):
a = [[[0 for _ in range(10)] for _ in range(10)] for _ in range(10)]
for n in range(len(text)-2):
i, j, k = (int(ss) for ss in text[n:n+3])
a[i][j][k] += 1
for i, b in enumerate(a):
for j, c in enumerate(b):
for k, d in enumerate(c):
if d > 1: yield (f'{i}{j}{k}', d)

for n in (1E1, 1E3, 1E6):
n = int(n)
data = setup_data(n)
print(f'n = {n}')
results = {}
for name, func in list(globals().items()):
if not name.startswith('f_') or not isinstance(func, types.FunctionType):
continue
print("{:16s}{:16.8f} ms".format(name[2:], timeit(
'results[name] = f(**data)', globals={'f':func, 'data':data, 'results':results, 'name':name}, number=10)*100))
for r in results:
print('{:10}: {}'.format(r, sorted(list(results[r]))[:5]))
``````

The array lookup method is very fast (even faster than @paul-panzer's numpy method!). Of course, it cheats since it isn't technicailly finished after it completes, because it's returning a generator. It also doesn't have to check every iteration if the value already exists, which is likely to help a lot.

``````n = 10
counter               0.10595780 ms
dict                  0.01070654 ms
array                 0.00135370 ms
f_counter : []
f_dict    : []
f_array   : []
n = 1000
counter               2.89462101 ms
dict                  0.40434612 ms
array                 0.00073838 ms
f_counter : [('008', 2), ('009', 3), ('010', 2), ('016', 2), ('017', 2)]
f_dict    : [('008', 2), ('009', 3), ('010', 2), ('016', 2), ('017', 2)]
f_array   : [('008', 2), ('009', 3), ('010', 2), ('016', 2), ('017', 2)]
n = 1000000
counter            2849.00500992 ms
dict                438.44007806 ms
array                 0.00135370 ms
f_counter : [('000', 1058), ('001', 943), ('002', 1030), ('003', 982), ('004', 1042)]
f_dict    : [('000', 1058), ('001', 943), ('002', 1030), ('003', 982), ('004', 1042)]
f_array   : [('000', 1058), ('001', 943), ('002', 1030), ('003', 982), ('004', 1042)]
``````
• So what are you comparing exactly? Shouldn't you return lists instead of unused generators? Dec 1 '17 at 13:20
• `Counters` aren't used that way. Used properly, they become the fastest option with your example. If you use `timeit` with a list insted of a generator, your method becomes slower than `Counter` or `dict`. See here. Dec 1 '17 at 13:39
• Finally, your `f_array` could be faster if you first convert every char to an int : `ints = [int(c) for c in text]` and then use `i, j, k = ints[n:n+3]`. Dec 1 '17 at 13:42 Looks like a sliding window.

Here is my solution:

``````from collections import defaultdict
string = "103264685134845354863"
d = defaultdict(int)
for elt in range(len(string)-2):
d[string[elt:elt+3]] += 1
d = {key: d[key] for key in d.keys() if d[key] > 1}
``````

With a bit of creativity in for loop(and additional lookup list with True/False/None for example) you should be able to get rid of last line, as you only want to create keys in dict that we visited once up to that point. Hope it helps :)

-Telling from the perspective of C. -You can have an int 3-d array results; -Go from 0th location to n-4th location, where n being the size of the string array. -On each location, check the current, next and next's next. -Increment the cntr as resutls[current][next][next's next]++; -Print the values of

``````results
results
results
results
results
results
results
``````

-It is O(n) time, there is no comparisons involved. -You can run some parallel stuff here by partitioning the array and calculating the matches around the partitions.

``````inputStr = '123456123138276237284287434628736482376487234682734682736487263482736487236482634'

count = {}
for i in range(len(inputStr) - 2):
subNum = int(inputStr[i:i+3])
if subNum not in count:
count[subNum] = 1
else:
count[subNum] += 1

print count
``````
• Thanks for your answer but it is too similar of an algorithm as was given by @abhishek arora 5-6 days ago. Also the original question was not asking for the algorithm but rather a different question (which was already answered multiple times) Dec 5 '17 at 14:57