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)
def add_element(self, element):
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)
def add_element(self, element):
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)
def add_element(self, element):
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.add_element(element)
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?