# Understanding Matrix to List of List and then Numpy Array

I want to construct a matrix like:

``````    Col1 Col2 Col3 Coln
row1  1    2    4    2
row2  3    8    3    3
row3  8    7    7    3
rown  n    n    n    n
``````

I have yet to find anything in the python documentation that states how a list of list is assembled, is it like:

``````a = [[1,2,4,2],[3,8,3,3],[8,7,7,3],[n,n,n,n]]
``````

Where each row is a list item or should it be that each column is a list item:

``````b = [[1,3,8,n],[2,8,7,n],[4,3,7,n],[2,3,3,n]]
``````

I would think that this would be a common question but I can't seem to find a straight answer.

Based on the documentation I'm guessing that I can convert this to a numpy array by simply:

``````np.array(a)
``````

Can anyone help?

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You can always test that you did it right by using `print(a)` which formats it so that you can tell what's a row and what's a column. –  askewchan Mar 4 '13 at 17:58

You want the first version:

``````a = [[1,2,4,2],[3,8,3,3],[8,7,7,3],[n,n,n,n]]
``````

When accessing an element in a matrix, you typically use `matrix[row][col]`, so with the above Python list format `a[i]` would give you row `i`, and `a[i][j]` would give you the jth element from the ith row.

To convert it to a numpy array, `np.array(a)` is the correct method.

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Thank you so much, both you and @drewk both provided exactly what I needed.. I appreciate the the straight talk, I find that a lot of the python related "features" could really use more forward explanations. Thanks again! –  secumind Mar 4 '13 at 18:04

Use the first convention. If transpose needed:

``````>>> a = [[1,2,4,2],[3,8,3,3],[8,7,7,3],['n','n','n','n']]
>>> trans=[]
>>> for i in range(len(a)):
...    trans.append([row[i] for row in a])
...
>>> trans
[[1, 3, 8, 'n'], [2, 8, 7, 'n'], [4, 3, 7, 'n'], [2, 3, 3, 'n']]
``````

An element is then `a[row][col]` vs `trans[col][row]` (with respect to `a` of your example)

The first is used by Python and that is easily seen why you should use the first convention when laid out:

``````a = [[1,2,4,2],
[3,8,3,3],
[8,7,7,3],
['n','n','n','n']]
``````

Certainly when you use numpy, use the first convention since that is used by numpy:

``````>>> np.array(a)
array([['1', '2', '4', '2'],
['3', '8', '3', '3'],
['8', '7', '7', '3'],
['n', 'n', 'n', 'n']],
dtype='|S1')
>>> np.array(trans)
array([['1', '3', '8', 'n'],
['2', '8', '7', 'n'],
['4', '3', '7', 'n'],
['2', '3', '3', 'n']],
dtype='|S1')
``````

Note: numpy converts the ints to strings because of the `'n'` in the final row/col.

When you actual start to print that table, here is a way:

``````def pprint_table(table):
def format_field(field, fmt='{:,.0f}'):
if type(field) is str: return field
if type(field) is tuple: return field[1].format(field[0])
return fmt.format(field)

def get_max_col_w(table, index):
return max([len(format_field(row[index])) for row in table])

col_paddings=[get_max_col_w(table, i) for i in range(len(table[0]))]
for i,row in enumerate(table):
# left col
# rest of the cols
print(' '.join(row_tab))

pprint_table([
['','Col 1', 'Col 2', 'Col 3', 'Col 4'],
['row 1', '1','2','4','2'],
['row 2','3','8','3','3'],
['row 3','8','7','7','3'],
['row 4', 'n','n','n','n']])
``````

Prints:

``````      Col 1 Col 2 Col 3 Col 4
row 1     1     2     4     2
row 2     3     8     3     3
row 3     8     7     7     3
row 4     n     n     n     n
``````
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This: `a = [[1,2,4,2],[3,8,3,3],[8,7,7,3],[n,n,n,n]]` will create the list you want, and yes, np.array(a) will convert it to a numpy array.

Also, this is the 'pythonish' was of creating an array with `m` rows and `n` columns (and setting all the elements to 0):

`a = [[0 for i in range(n)] for j in range(m)]`

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Since you mention "matrix" let me also add that you have the np.matrix() option as well.

For example: You can use

``````A = [[1,2,3],[4,5,6],[7,8,9]]
``````

to create a list (of lists), with each inner list representing a row.

Then

``````AA = np.array(A)
``````

will create a 2D array with the appearance of a matrix, but not all the properties of a matrix.

Whereas

``````AM = np.matrix(A)
``````

will create a matrix.

If you perform arithmetic operations on these two then you'll see the difference. For example

``````AA**2
``````

will square each element in the 2D array. However

``````AM**2
``````

will perform matrix multiplication of AM by itself.

BTW. The above usage assumes "import numpy as np" of course.

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