```
dist = numpy.linalg.norm(a-b)
```

Is a nice one line answer. However, if speed is a concern I would recommend experimenting on your machine. I found that using the `math`

library's `sqrt`

with the `**`

operator for the square is much faster on my machine than the one line, numpy solution.

I ran my tests using this simple program:

```
#!/usr/bin/python
import math
import numpy
from random import uniform
def fastest_calc_dist(p1,p2):
return math.sqrt((p2[0] - p1[0]) ** 2 +
(p2[1] - p1[1]) ** 2 +
(p2[2] - p1[2]) ** 2)
def math_calc_dist(p1,p2):
return math.sqrt(math.pow((p2[0] - p1[0]), 2) +
math.pow((p2[1] - p1[1]), 2) +
math.pow((p2[2] - p1[2]), 2))
def numpy_calc_dist(p1,p2):
return numpy.linalg.norm(numpy.array(p1)-numpy.array(p2))
TOTAL_LOCATIONS = 1000
p1 = dict()
p2 = dict()
for i in range(0, TOTAL_LOCATIONS):
p1[i] = (uniform(0,1000),uniform(0,1000),uniform(0,1000))
p2[i] = (uniform(0,1000),uniform(0,1000),uniform(0,1000))
total_dist = 0
for i in range(0, TOTAL_LOCATIONS):
for j in range(0, TOTAL_LOCATIONS):
dist = fastest_calc_dist(p1[i], p2[j]) #change this line for testing
total_dist += dist
print total_dist
```

On my machine, `math_calc_dist`

runs much faster than `numpy_calc_dist`

: **1.5 seconds** versus **23.5 seconds**.

To get a measurable difference between `fastest_calc_dist`

and `math_calc_dist`

I had to up `TOTAL_LOCATIONS`

to 6000. Then `fastest_calc_dist`

takes **~50 seconds** while `math_calc_dist`

takes **~60 seconds**.

You can also experiment with `numpy.sqrt`

and `numpy.square`

though both were slower than the `math`

alternatives on my machine.

My tests were run with Python 2.6.6.