# numpy.concatenate multidimensional arrays

I'm searching for an algorithm to merge a given number of multidimensional arrays (each of the same shape) to a given proportion (x,y,z).

For example 4 arrays with the shape (128,128,128) and the proportion (1,1,4) to an array of the shape (128,128,512). Or 2 arrays with the shape (64,64,64) and the proportion (1,2,1) to an array of the shape (64,128,64)

I know how to do it manually with `np.concatenate`, but I need a general algorithm to do this. (`np.reshape` doesn't work - this will mess up the order)

edit: It's possible that the proportion is (1,2,3), then it is necessary to compare the left_edge of the box, to know where to place it. every array have a corresponding block with the attribute left_edge (xmin, ymin, zmin). Can I solve this with a if-condition?

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"2 arrays with the shape (64,64)" - is their shape `(64,64,64)`? –  eumiro Jan 4 at 9:36
sorry, my fault - you are right. –  Christian Jan 4 at 10:16

If your proportion is always one-dimensional (i.e. concatenate in one dimension only), you can use this:

``````arrays = [...]
proportion = (1,1,4)

np.concatenate(arrays, axis=next(i for i,p in enumerate(proportion) if p>1))
``````

Otherwise you have to explain what to do with `proportion = (1,2,3)`

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Thanks for your answer. I edited my question, cause there are more complicate proportions. –  Christian Jan 4 at 10:22

Okay I programmed it this way and it seems to work. Maybe not the nicest way, but it do what I want.

``````blocks.sort(key=lambda x: (x.left_edge[2],x.left_edge[1],x.left_edge[0]))
proportion = (Nx * nblockx, Ny * nblocky, Nz * nblockz)

arrays = np.zeros((nblockx, nblocky, nblockz, Nx, Ny, Nz))

for block, (x,y,z) in zip(root_list,
product(range(nblockx),
range(nblocky),
range(nblockz))):
array = np.zeros((Nx, Ny, Nz), dtype = np.float64)

# this is only the function to fill the array
writearray(array, ...)

arrays[x,y,z] = array

shape = arrays.shape
array = np.zeros((shape[0]*shape[3], shape[1]*shape[4], shape[2]*shape[5]))
for x,y,z in product(range(shape[0]), range(shape[1]), range(shape[2])):
slicex = slice(x*shape[3], (x+1)*shape[3])
slicey = slice(y*shape[4], (y+1)*shape[4])
slicez = slice(z*shape[5], (z+1)*shape[5])

array[slicex, slicey, slicez] = arrays[x,y,z]

return array
``````
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