*This is a follow up to this answer to my previous question Fastest approach to read thousands of images into one big numpy array.*

In chapter 2.3 "Memory allocation of the ndarray", Travis Oliphant writes the following regarding how indexes are accessed in memory for C-ordered numpy arrays.

...to move through computer memory sequentially, the last index is incremented first, followed by the second-to-last index and so forth.

This can be confirmed by benchmarking the accessing time of 2-D arrays either along the two first or the two last indexes (for my purposes, this is a simulation of loading 500 images of size 512x512 pixels):

```
import numpy as np
N = 512
n = 500
a = np.random.randint(0,255,(N,N))
def last_and_second_last():
'''Store along the two last indexes'''
imgs = np.empty((n,N,N), dtype='uint16')
for num in range(n):
imgs[num,:,:] = a
return imgs
def second_and_third_last():
'''Store along the two first indexes'''
imgs = np.empty((N,N,n), dtype='uint16')
for num in range(n):
imgs[:,:,num] = a
return imgs
```

Benchmark

```
In [2]: %timeit last_and_second_last()
136 ms ± 2.18 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
In [3]: %timeit second_and_third_last()
1.56 s ± 10.9 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
```

So far so good. However, when I load arrays along the last and third last dimension, this is almost as fast as loading them into the two last dimensions.

```
def last_and_third_last():
'''Store along the last and first indexes'''
imgs = np.empty((N,n,N), dtype='uint16')
for num in range(n):
imgs[:,num,:] = a
return imgs
```

Benchmark

```
In [4]: %timeit last_and_third_last()
149 ms ± 227 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
```

- Why is it that
`last_and_third_last()`

is so my closer in speed to`last_and_second_last()`

compared to`second_and third_last()`

? - What's a good way to visualize why the last index matters much more than the second last index in regards to the accessing speed?