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)
andnp.array(m)
will copy both, because that's the default behavior.np.array(a, copy=False)
andnp.array(m, copy=False)
will copym
but nota
, becausem
is not anndarray
.np.array(a, copy=False, subok=True)
andnp.array(m, copy=False, subok=True)
will copy neither, becausem
is amatrix
, which is a subclass ofndarray
.np.array(a, dtype=int, copy=False, subok=True)
will copy both, because thedtype
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 compatiblendarray
(copy=False
).asanyarray
: The input will be returned uncopied iff it's a compatiblendarray
or subclass likematrix
(copy=False
,subok=True
).ascontiguousarray
: The input will be returned uncopied iff it's a compatiblendarray
in contiguous C order (copy=False
,order='C')
.asfortranarray
: The input will be returned uncopied iff it's a compatiblendarray
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 anobject
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).
The definition of asarray
is:
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.

11So when should we use each? If creating an array from scratch, which is better,
array([1, 2, 3])
orasarray([1, 2, 3])
? – endolith Jun 2 '14 at 23:25 
12@endolith:
[1, 2, 3]
is a Python list, so a copy of the data must be made to create thendarary
. So usenp.array
directly instead ofnp.asarray
which would send thecopy=False
parameter tonp.array
. Thecopy=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 
2That 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

1

2@Lee:
asarray
always returns anndarray
.asanyarray
will return a subclass ofndarray
if that is what was passed to it. For example, annp.matrix
is a subclass ofndarray
. Sonp.asanyarray(np.matrix(...))
returns the same matrix, whereasnp.asarray(np.matrix(...))
converts the matrix to anndarray
. – unutbu Jul 26 '16 at 16:34
The difference can be demonstrated by this example:
generate a matrix
>>> A = numpy.matrix(np.ones((3,3))) >>> A matrix([[ 1., 1., 1.], [ 1., 1., 1.], [ 1., 1., 1.]])
use
numpy.array
to modifyA
. 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.]])
use
numpy.asarray
to modifyA
. It worked because you are modifyingA
itself>>> numpy.asarray(A)[2]=2 >>> A matrix([[ 1., 1., 1.], [ 1., 1., 1.], [ 2., 2., 2.]])
Hope this helps!

13
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 subclasses will be passedthrough, otherwise the returned array will be forced to be a baseclass array (default).
ndmin : int, optional Specifies the minimum number of dimensions that the resulting array should have. Ones will be prepended 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.