# What is the difference between contiguous and non-contiguous arrays?

In the numpy manual about the reshape() function, it says

``````>>> a = np.zeros((10, 2))
# A transpose make the array non-contiguous
>>> b = a.T
# Taking a view makes it possible to modify the shape without modifying the
# initial object.
>>> c = b.view()
>>> c.shape = (20)
AttributeError: incompatible shape for a non-contiguous array
``````

My questions are:

1. What are continuous and noncontiguous arrays? Is it similar to the contiguous memory block in C like What is a contiguous memory block?
2. Is there any performance difference between these two? When should we use one or the other?
3. Why does transpose make the array non-contiguous?
4. Why does `c.shape = (20)` throws an error `incompatible shape for a non-contiguous array`?

A contiguous array is just an array stored in an unbroken block of memory: to access the next value in the array, we just move to the next memory address.

Consider the 2D array `arr = np.arange(12).reshape(3,4)`. It looks like this: In the computer's memory, the values of `arr` are stored like this: This means `arr` is a C contiguous array because the rows are stored as contiguous blocks of memory. The next memory address holds the next row value on that row. If we want to move down a column, we just need to jump over three blocks (e.g. to jump from 0 to 4 means we skip over 1,2 and 3).

Transposing the array with `arr.T` means that C contiguity is lost because adjacent row entries are no longer in adjacent memory addresses. However, `arr.T` is Fortran contiguous since the columns are in contiguous blocks of memory: Performance-wise, accessing memory addresses which are next to each other is very often faster than accessing addresses which are more "spread out" (fetching a value from RAM could entail a number of neighbouring addresses being fetched and cached for the CPU.) This means that operations over contiguous arrays will often be quicker.

As a consequence of C contiguous memory layout, row-wise operations are usually faster than column-wise operations. For example, you'll typically find that

``````np.sum(arr, axis=1) # sum the rows
``````

is slightly faster than:

``````np.sum(arr, axis=0) # sum the columns
``````

Similarly, operations on columns will be slightly faster for Fortran contiguous arrays.

Finally, why can't we flatten the Fortran contiguous array by assigning a new shape?

``````>>> arr2 = arr.T
>>> arr2.shape = 12
AttributeError: incompatible shape for a non-contiguous array
``````

In order for this to be possible NumPy would have to put the rows of `arr.T` together like this: (Setting the `shape` attribute directly assumes C order - i.e. NumPy tries to perform the operation row-wise.)

This is impossible to do. For any axis, NumPy needs to have a constant stride length (the number of bytes to move) to get to the next element of the array. Flattening `arr.T` in this way would require skipping forwards and backwards in memory to retrieve consecutive values of the array.

If we wrote `arr2.reshape(12)` instead, NumPy would copy the values of arr2 into a new block of memory (since it can't return a view on to the original data for this shape).

Maybe this example with 12 different array values will help:

``````In : x=np.arange(12).reshape(3,4).copy()

In : x.flags
Out:
C_CONTIGUOUS : True
F_CONTIGUOUS : False
OWNDATA : True
...
In : x.T.flags
Out:
C_CONTIGUOUS : False
F_CONTIGUOUS : True
OWNDATA : False
...
``````

The `C order` values are in the order that they were generated in. The transposed ones are not

``````In : x.reshape(12,)   # same as x.ravel()
Out: array([ 0,  1,  2,  3,  4,  5,  6,  7,  8,  9, 10, 11])

In : x.T.reshape(12,)
Out: array([ 0,  4,  8,  1,  5,  9,  2,  6, 10,  3,  7, 11])
``````

You can get 1d views of both

``````In : x1=x.T

In : x.shape=(12,)
``````

the shape of `x` can also be changed.

``````In : x1.shape=(12,)
---------------------------------------------------------------------------
AttributeError                            Traceback (most recent call last)
<ipython-input-220-cf2b1a308253> in <module>()
----> 1 x1.shape=(12,)

AttributeError: incompatible shape for a non-contiguous array
``````

But the shape of the transpose cannot be changed. The `data` is still in the `0,1,2,3,4...` order, which can't be accessed accessed as `0,4,8...` in a 1d array.

But a copy of `x1` can be changed:

``````In : x2=x1.copy()

In : x2.flags
Out:
C_CONTIGUOUS : True
F_CONTIGUOUS : False
OWNDATA : True
...
In : x2.shape=(12,)
``````

Looking at `strides` might also help. A strides is how far (in bytes) it has to step to get to the next value. For a 2d array, there will be be 2 stride values:

``````In : x=np.arange(12).reshape(3,4).copy()

In : x.strides
Out: (16, 4)
``````

To get to the next row, step 16 bytes, next column only 4.

``````In : x1.strides
Out: (4, 16)
``````

Transpose just switches the order of the strides. The next row is only 4 bytes- i.e. the next number.

``````In : x.shape=(12,)

In : x.strides
Out: (4,)
``````

Changing the shape also changes the strides - just step through the buffer 4 bytes at a time.

``````In : x2=x1.copy()

In : x2.strides
Out: (12, 4)
``````

Even though `x2` looks just like `x1`, it has its own data buffer, with the values in a different order. The next column is now 4 bytes over, while the next row is 12 (3*4).

``````In : x2.shape=(12,)

In : x2.strides
Out: (4,)
``````

And as with `x`, changing the shape to 1d reduces the strides to `(4,)`.

For `x1`, with data in the `0,1,2,...` order, there isn't a 1d stride that would give `0,4,8...`.

`__array_interface__` is another useful way of displaying array information:

``````In : x1.__array_interface__
Out:
{'strides': (4, 16),
'typestr': '<i4',
'shape': (4, 3),
'version': 3,
'data': (163336056, False),
'descr': [('', '<i4')]}
``````

The `x1` data buffer address will be same as for `x`, with which it shares the data. `x2` has a different buffer address.

You could also experiment with adding a `order='F'` parameter to the `copy` and `reshape` commands.