polynomial.polynomial.polyone = array([1])#

An array object represents a multidimensional, homogeneous array of fixed-size items. An associated data-type object describes the format of each element in the array (its byte-order, how many bytes it occupies in memory, whether it is an integer, a floating point number, or something else, etc.)

Arrays should be constructed using array, zeros or empty (refer to the See Also section below). The parameters given here refer to a low-level method (ndarray(…)) for instantiating an array.

For more information, refer to the numpy module and examine the methods and attributes of an array.

(for the __new__ method; see Notes below)
shapetuple of ints

Shape of created array.

dtypedata-type, optional

Any object that can be interpreted as a numpy data type.

bufferobject exposing buffer interface, optional

Used to fill the array with data.

offsetint, optional

Offset of array data in buffer.

stridestuple of ints, optional

Strides of data in memory.

order{‘C’, ‘F’}, optional

Row-major (C-style) or column-major (Fortran-style) order.

See also


Construct an array.


Create an array, each element of which is zero.


Create an array, but leave its allocated memory unchanged (i.e., it contains “garbage”).


Create a data-type.


An ndarray alias generic w.r.t. its dtype.type.


There are two modes of creating an array using __new__:

  1. If buffer is None, then only shape, dtype, and order are used.

  2. If buffer is an object exposing the buffer interface, then all keywords are interpreted.

No __init__ method is needed because the array is fully initialized after the __new__ method.


These examples illustrate the low-level ndarray constructor. Refer to the See Also section above for easier ways of constructing an ndarray.

First mode, buffer is None:

>>> np.ndarray(shape=(2,2), dtype=float, order='F')
array([[0.0e+000, 0.0e+000], # random
       [     nan, 2.5e-323]])

Second mode:

>>> np.ndarray((2,), buffer=np.array([1,2,3]),
...            offset=np.int_().itemsize,
...            dtype=int) # offset = 1*itemsize, i.e. skip first element
array([2, 3])

Transpose of the array.


The array’s elements, in memory.

dtypedtype object

Describes the format of the elements in the array.


Dictionary containing information related to memory use, e.g., ‘C_CONTIGUOUS’, ‘OWNDATA’, ‘WRITEABLE’, etc.

flatnumpy.flatiter object

Flattened version of the array as an iterator. The iterator allows assignments, e.g., x.flat = 3 (See ndarray.flat for assignment examples; TODO).


Imaginary part of the array.


Real part of the array.


Number of elements in the array.


The memory use of each array element in bytes.


The total number of bytes required to store the array data, i.e., itemsize * size.


The array’s number of dimensions.

shapetuple of ints

Shape of the array.

stridestuple of ints

The step-size required to move from one element to the next in memory. For example, a contiguous (3, 4) array of type int16 in C-order has strides (8, 2). This implies that to move from element to element in memory requires jumps of 2 bytes. To move from row-to-row, one needs to jump 8 bytes at a time (2 * 4).

ctypesctypes object

Class containing properties of the array needed for interaction with ctypes.


If the array is a view into another array, that array is its base (unless that array is also a view). The base array is where the array data is actually stored.