# Numpy - array vs asarray

What is the difference between Numpy's `array()` and `asarray()` functions? When should you use one rather than the other? They seem to generate identical output for all the inputs I can think of.

Since other questions are being redirected to this one which ask about `asanyarray` or other array creation routines, it's probably worth having a brief summary of what each of them does.

The differences are mainly about when to return the input unchanged, as opposed to making a new array as a copy.

`array` offers a wide variety of options (most of the other functions are thin wrappers around it), including flags to determine when to copy. A full explanation would take just as long as the docs (see Array Creation, but briefly, here are some examples:

Assume `a` is an `ndarray`, and `m` is a `matrix`, and they both have a `dtype` of `float32`:

• `np.array(a)` and `np.array(m)` will copy both, because that's the default behavior.
• `np.array(a, copy=False)` and `np.array(m, copy=False)` will copy `m` but not `a`, because `m` is not an `ndarray`.
• `np.array(a, copy=False, subok=True)` and `np.array(m, copy=False, subok=True)` will copy neither, because `m` is a `matrix`, which is a subclass of `ndarray`.
• `np.array(a, dtype=int, copy=False, subok=True)` will copy both, because the `dtype` is not compatible.

Most of the other functions are thin wrappers around `array` that control when copying happens:

• `asarray`: The input will be returned uncopied iff it's a compatible `ndarray` (`copy=False`).
• `asanyarray`: The input will be returned uncopied iff it's a compatible `ndarray` or subclass like `matrix` (`copy=False`, `subok=True`).
• `ascontiguousarray`: The input will be returned uncopied iff it's a compatible `ndarray` in contiguous C order (`copy=False`, `order='C')`.
• `asfortranarray`: The input will be returned uncopied iff it's a compatible `ndarray` in contiguous Fortran order (`copy=False`, `order='F'`).
• `require`: The input will be returned uncopied iff it's compatible with the specified requirements string.
• `copy`: The input is always copied.
• `fromiter`: The input is treated as an iterable (so, e.g., you can construct an array from an iterator's elements, instead of an `object` array with the iterator); always copied.

There are also convenience functions, like `asarray_chkfinite` (same copying rules as `asarray`, but raises `ValueError` if there are any `nan` or `inf` values), and constructors for subclasses like `matrix` or for special cases like record arrays, and of course the actual `ndarray` constructor (which lets you create an array directly out of strides over a buffer).

``````def asarray(a, dtype=None, order=None):
return array(a, dtype, copy=False, order=order)
``````

So it is like `array`, except it has fewer options, and `copy=False`. `array` has `copy=True` by default.

The main difference is that `array` (by default) will make a copy of the object, while `asarray` will not unless necessary.

• So when should we use each? If creating an array from scratch, which is better, `array([1, 2, 3])` or `asarray([1, 2, 3])`? – endolith Jun 2 '14 at 23:25
• @endolith: `[1, 2, 3]` is a Python list, so a copy of the data must be made to create the `ndarary`. So use `np.array` directly instead of `np.asarray` which would send the `copy=False` parameter to `np.array`. The `copy=False` is ignored if a copy must be made as it would be in this case. If you benchmark the two using `%timeit` in IPython you'll see a difference for small lists, but it hardly matters which you use for large lists. – unutbu Jun 2 '14 at 23:43
• That makes sense per the method names too: "asarray": Treat this as an array (inplace), i.e., you're sort of just changing your view on this list/array. "array": Actually convert this to a new array. – denvar May 4 '16 at 18:41
• how about `np.asanyarray`? – Lee Jul 26 '16 at 16:29
• @Lee: `asarray` always returns an `ndarray`. `asanyarray` will return a subclass of `ndarray` if that is what was passed to it. For example, an `np.matrix` is a subclass of `ndarray`. So `np.asanyarray(np.matrix(...))` returns the same matrix, whereas `np.asarray(np.matrix(...))` converts the matrix to an `ndarray`. – unutbu Jul 26 '16 at 16:34

The difference can be demonstrated by this example:

1. generate a matrix

``````>>> A = numpy.matrix(np.ones((3,3)))
>>> A
matrix([[ 1.,  1.,  1.],
[ 1.,  1.,  1.],
[ 1.,  1.,  1.]])
``````
2. use `numpy.array` to modify `A`. Doesn't work because you are modifying a copy

``````>>> numpy.array(A)[2]=2
>>> A
matrix([[ 1.,  1.,  1.],
[ 1.,  1.,  1.],
[ 1.,  1.,  1.]])
``````
3. use `numpy.asarray` to modify `A`. It worked because you are modifying `A` itself

``````>>> numpy.asarray(A)[2]=2
>>> A
matrix([[ 1.,  1.,  1.],
[ 1.,  1.,  1.],
[ 2.,  2.,  2.]])
``````

Hope this helps!

• Finally someone gives an example.. Thank you so much! – CapturedTree Mar 13 '17 at 21:52

The differences are mentioned quite clearly in the documentation of `array` and `asarray`. The differences lie in the argument list and hence the action of the function depending on those parameters.

The function definitions are :

``````numpy.array(object, dtype=None, copy=True, order=None, subok=False, ndmin=0)
``````

and

``````numpy.asarray(a, dtype=None, order=None)
``````

The following arguments are those that may be passed to `array` and not `asarray` as mentioned in the documentation :

copy : bool, optional If true (default), then the object is copied. Otherwise, a copy will only be made if `__array__` returns a copy, if obj is a nested sequence, or if a copy is needed to satisfy any of the other requirements (dtype, order, etc.).

subok : bool, optional If True, then sub-classes will be passed-through, otherwise the returned array will be forced to be a base-class array (default).

ndmin : int, optional Specifies the minimum number of dimensions that the resulting array should have. Ones will be pre-pended to the shape as needed to meet this requirement.

Here's a simple example that can demonstrate the difference.

The main difference is that array will make a copy of the original data and using different object we can modify the data in the original array.

``````import numpy as np
a = np.arange(0.0, 10.2, 0.12)
int_cvr = np.asarray(a, dtype = np.int64)
``````

The contents in array (a), remain untouched, and still, we can perform any operation on the data using another object without modifying the content in original array.