I want to implement the following routine without using loops, just using Numpy functions or ndarray methods. Here is the code:

```
def split_array_into_blocks( the_array, block_dim, total_blocks_per_row ):
n_grid = the_array.shape[0]
res = np.empty( (n_grid, total_blocks_per_row, total_blocks_per_row, block_dim,
block_dim ) )
for i in range( total_blocks_per_row ):
for j in range( total_blocks_per_row ):
subblock = the_array[ :, block_dim*i:block_dim*(i+1), block_dim*j:block_dim*(j+1) ]
res[ :, i,j,:,: ] = subblock
return res
```

I have tried with the "reshape" method so that:

```
the_array = the_array.reshape( ( n_grid, total_blocks_per_row, total_blocks_per_row, block_dim, block_dim) )
```

but this seems to change the order of the elements in some way, and the blocks needs to be stored exactly as in the routine. Can anyone provide a way to do this, with a short explanation of why the reshape method gives a different result here? (maybe I am missing using the np.transpose() in addition?)

**EDIT:** I came up with this alternative implementation, but I am still not sure if this is the most efficient way (maybe someone can shed some light here):

```
def split_array_in_blocks( the_array, block_dim, total_blocks_per_row ):
indx = [ block_dim*j for j in range( 1, total_blocks_per_row ) ]
the_array = np.array( [ np.split( np.split( the_array, indx, axis=1 )[j], indx, axis=-1 ) for j in range( total_blocks_per_row ) ] )
the_array = np.transpose( the_array, axes=( 2,0,1,3,4 ) )
return the_array
```

**EXAMPLE:** Here is a minimal working example for the two implementations. What we want is, from an initial "cube" of dimensions Nx3*MX3*M, decompose into blocks NxMxMx3x3, which are the chunked version of the original block. With the two implementations above, one can check that they give the same result; the question is on how to achieve this in an efficient way (i.e., no loops)

```
import numpy as np
def split_array_in_blocks_2( the_array, block_dim, total_blocks_per_row ):
n_grid = the_array.shape[0]
res = np.zeros( (n_grid, total_blocks_per_row, total_blocks_per_row, block_dim, block_dim ), dtype=the_array.dtype )
for i in range( total_blocks_per_row ):
for j in range( total_blocks_per_row ):
subblock = the_array[ :, block_dim*i:block_dim*(i+1), block_dim*j:block_dim*(j+1) ]
res[ :, i,j,:,: ] = subblock
return res
def split_array_in_blocks( the_array, block_dim, total_blocks_per_row ):
indx = [ block_dim*j for j in range( 1, total_blocks_per_row ) ]
the_array = np.array( [ np.split( np.split( the_array, indx, axis=1 )[j], indx, axis=-1 ) for j in range( total_blocks_per_row ) ] )
the_array = np.transpose( the_array, axes=( 2,0,1,3,4 ) )
return the_array
A = np.random.rand( 1001, 63, 63 )
n = 3
D = 21
from time import time
ts = time()
An = split_array_in_blocks( A, n, D )
t2 = time()
Bn = split_array_in_blocks_2( A, n, D )
t3 = time()
print( t2-ts )
print(t3-t2)
print(np.allclose( An, Bn ))
```