# Why does numpy.median scale so well?

A question I recently got at a job interview, was:

Write a data structure that supports two operations.
1. Adding a number to the structure.
2. Calculating the median.
The operations to add a number and calculate the median must have a minimum time complexity.

My implementation was pretty simple, basically keep the elements sorted, this way adding an elements costs O(log(n)) instead of O(1), but the median is O(1) instead of O(n*log(n))

I also added an implementation that is naive, but contains the elements in a numpy array:

import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
from random import randint, random
import math
from time import time

class MedianList():
def __init__(self, initial_values = []):
self.values = sorted(initial_values)
self.size = len(initial_values)

index = self.find_pos(self.values, element)
self.values = self.values[:index] + [element] + self.values[index:]
self.size += 1

def find_pos(self, values, element):
if len(values) == 0: return 0
index = int(len(values)/2)
if element > values[index]:
return self.find_pos(values[index+1:], element) + index +  1
if element < values[index]:
return self.find_pos(values[:index], element)
if element == values[index]: return index

def median(self):
if self.size == 0: return np.nan
split = math.floor(self.size/2)
if self.size % 2 == 1:
return self.values[split]
try:
return (self.values[split] + self.values[split-1])/2
except:
print(self.values, self.size, split)

class NaiveMedianList():
def __init__(self, initial_values = []):
self.values = sorted(initial_values)

self.values.append(element)

def median(self):
split = math.floor(len(self.values)/2)
sorted_values = sorted(self.values)
if len(self.values) % 2 == 1:
return sorted_values[split]
return (sorted_values[split] + sorted_values[split-1])/2

class NumpyMedianList():
def __init__(self, initial_values = []):
self.values = np.array(initial_values)

self.values = np.append(self.values, element)

def median(self):
return np.median(self.values)

def time_performance(median_list, total_elements = 10**5):
elements = [randint(0, 100) for _ in range(total_elements)]
times = []
start = time()
for element in elements:
median_list.median()
times.append(time() - start)
return times

ml_times = time_performance(MedianList())
nl_times = time_performance(NaiveMedianList())
npl_times = time_performance(NumpyMedianList())
times = pd.DataFrame()
times['MedianList'] = ml_times
times['NaiveMedianList'] = nl_times
times['NumpyMedianList'] = npl_times
times.plot()
plt.show()

And here is how the performances look, for 10^4 elements:

And for 10^5 elements, the naive numpy implementation is actually faster:

My question is: How come? Even if numpy is faster by a constant factor, how is their median function scaling so well, if they do not keep a sorted version of the array?

• There are algorithms that can find the median in linear time, O(n), even for unsorted arrays. Here is one reference: do a web search for "fast median algorithm" for others. Numpy probably uses a variation on one of those. It is not necessary to sort the list before finding the median, though that is the naïve algorithm. – Rory Daulton Jun 17 '18 at 18:52
• one should also have a look at en.wikipedia.org/wiki/Quickselect#Variants as it is related – zython Jun 17 '18 at 19:51
• @RoryDaulton Thanks a lot, that answers my question. – Hristo Buyukliev Jun 17 '18 at 22:57
• Would a simple binary tree not be optimal? O(logn) insert+balance and O(1) for retrieval? – David Jun 18 '18 at 4:35
• If you make a small tweak of allowing the root node to hold one or two numbers depending on if you have an odd number of numbers or not, then the retrieval only needs to look at the root node which would be O(1). – David Jun 18 '18 at 16:54

We can inspect the Numpy source code for median (source):

def median(a, axis=None, out=None, overwrite_input=False, keepdims=False):
...

if overwrite_input:
if axis is None:
part = a.ravel()
part.partition(kth)
else:
a.partition(kth, axis=axis)
part = a
else:
part = partition(a, kth, axis=axis)

...

The key function is partition, which from the docs, uses introselect. As @zython commented, this is a variant of Quickselect, which provides the critical performance boost.