Writing custom array containers¶
Numpy’s dispatch mechanism, introduced in numpy version v1.16 is the recommended approach for writing custom N-dimensional array containers that are compatible with the numpy API and provide custom implementations of numpy functionality. Applications include dask arrays, an N-dimensional array distributed across multiple nodes, and cupy arrays, an N-dimensional array on a GPU.
To get a feel for writing custom array containers, we’ll begin with a simple example that has rather narrow utility but illustrates the concepts involved.
>>> import numpy as np
>>> class DiagonalArray:
... def __init__(self, N, value):
... self._N = N
... self._i = value
... def __repr__(self):
... return f"{self.__class__.__name__}(N={self._N}, value={self._i})"
... def __array__(self):
... return self._i * np.eye(self._N)
...
Our custom array can be instantiated like:
>>> arr = DiagonalArray(5, 1)
>>> arr
DiagonalArray(N=5, value=1)
We can convert to a numpy array using numpy.array
or
numpy.asarray
, which will call its __array__
method to obtain a
standard numpy.ndarray
.
>>> np.asarray(arr)
array([[1., 0., 0., 0., 0.],
[0., 1., 0., 0., 0.],
[0., 0., 1., 0., 0.],
[0., 0., 0., 1., 0.],
[0., 0., 0., 0., 1.]])
If we operate on arr
with a numpy function, numpy will again use the
__array__
interface to convert it to an array and then apply the function
in the usual way.
>>> np.multiply(arr, 2)
array([[2., 0., 0., 0., 0.],
[0., 2., 0., 0., 0.],
[0., 0., 2., 0., 0.],
[0., 0., 0., 2., 0.],
[0., 0., 0., 0., 2.]])
Notice that the return type is a standard numpy.ndarray
.
>>> type(arr)
numpy.ndarray
How can we pass our custom array type through this function? Numpy allows a
class to indicate that it would like to handle computations in a custom-defined
way through the interaces __array_ufunc__
and __array_function__
. Let’s
take one at a time, starting with _array_ufunc__
. This method covers
Universal functions (ufunc), a class of functions that includes, for example,
numpy.multiply
and numpy.sin
.
The __array_ufunc__
receives:
ufunc
, a function likenumpy.multiply
method
, a string, differentiating betweennumpy.multiply(...)
and variants likenumpy.multiply.outer
,numpy.multiply.accumulate
, and so on. For the common case,numpy.multiply(...)
,method == '__call__'
.inputs
, which could be a mixture of different typeskwargs
, keyword arguments passed to the function
For this example we will only handle the method '__call__
.
>>> from numbers import Number
>>> class DiagonalArray:
... def __init__(self, N, value):
... self._N = N
... self._i = value
... def __repr__(self):
... return f"{self.__class__.__name__}(N={self._N}, value={self._i})"
... def __array__(self):
... return self._i * np.eye(self._N)
... def __array_ufunc__(self, ufunc, method, *inputs, **kwargs):
... if method == '__call__':
... N = None
... scalars = []
... for input in inputs:
... if isinstance(input, Number):
... scalars.append(input)
... elif isinstance(input, self.__class__):
... scalars.append(input._i)
... if N is not None:
... if N != self._N:
... raise TypeError("inconsistent sizes")
... else:
... N = self._N
... else:
... return NotImplemented
... return self.__class__(N, ufunc(*scalars, **kwargs))
... else:
... return NotImplemented
...
Now our custom array type passes through numpy functions.
>>> arr = DiagonalArray(5, 1)
>>> np.multiply(arr, 3)
DiagonalArray(N=5, value=3)
>>> np.add(arr, 3)
DiagonalArray(N=5, value=4)
>>> np.sin(arr)
DiagonalArray(N=5, value=0.8414709848078965)
At this point arr + 3
does not work.
>>> arr + 3
TypeError: unsupported operand type(s) for *: 'DiagonalArray' and 'int'
To support it, we need to define the Python interfaces __add__
, __lt__
,
and so on to dispatch to the corresponding ufunc. We can achieve this
conveniently by inheriting from the mixin
NDArrayOperatorsMixin
.
>>> import numpy.lib.mixins
>>> class DiagonalArray(numpy.lib.mixins.NDArrayOperatorsMixin):
... def __init__(self, N, value):
... self._N = N
... self._i = value
... def __repr__(self):
... return f"{self.__class__.__name__}(N={self._N}, value={self._i})"
... def __array__(self):
... return self._i * np.eye(self._N)
... def __array_ufunc__(self, ufunc, method, *inputs, **kwargs):
... if method == '__call__':
... N = None
... scalars = []
... for input in inputs:
... if isinstance(input, Number):
... scalars.append(input)
... elif isinstance(input, self.__class__):
... scalars.append(input._i)
... if N is not None:
... if N != self._N:
... raise TypeError("inconsistent sizes")
... else:
... N = self._N
... else:
... return NotImplemented
... return self.__class__(N, ufunc(*scalars, **kwargs))
... else:
... return NotImplemented
...
>>> arr = DiagonalArray(5, 1)
>>> arr + 3
DiagonalArray(N=5, value=4)
>>> arr > 0
DiagonalArray(N=5, value=True)
Now let’s tackle __array_function__
. We’ll create dict that maps numpy
functions to our custom variants.
>>> HANDLED_FUNCTIONS = {}
>>> class DiagonalArray(numpy.lib.mixins.NDArrayOperatorsMixin):
... def __init__(self, N, value):
... self._N = N
... self._i = value
... def __repr__(self):
... return f"{self.__class__.__name__}(N={self._N}, value={self._i})"
... def __array__(self):
... return self._i * np.eye(self._N)
... def __array_ufunc__(self, ufunc, method, *inputs, **kwargs):
... if method == '__call__':
... N = None
... scalars = []
... for input in inputs:
... # In this case we accept only scalar numbers or DiagonalArrays.
... if isinstance(input, Number):
... scalars.append(input)
... elif isinstance(input, self.__class__):
... scalars.append(input._i)
... if N is not None:
... if N != self._N:
... raise TypeError("inconsistent sizes")
... else:
... N = self._N
... else:
... return NotImplemented
... return self.__class__(N, ufunc(*scalars, **kwargs))
... else:
... return NotImplemented
... def __array_function__(self, func, types, args, kwargs):
... if func not in HANDLED_FUNCTIONS:
... return NotImplemented
... # Note: this allows subclasses that don't override
... # __array_function__ to handle DiagonalArray objects.
... if not all(issubclass(t, self.__class__) for t in types):
... return NotImplemented
... return HANDLED_FUNCTIONS[func](*args, **kwargs)
...
A convenient pattern is to define a decorator implements
that can be used
to add functions to HANDLED_FUNCTIONS
.
>>> def implements(np_function):
... "Register an __array_function__ implementation for DiagonalArray objects."
... def decorator(func):
... HANDLED_FUNCTIONS[np_function] = func
... return func
... return decorator
...
Now we write implementations of numpy functions for DiagonalArray
.
For completeness, to support the usage arr.sum()
add a method sum
that
calls numpy.sum(self)
, and the same for mean
.
>>> @implements(np.sum)
... def sum(a):
... "Implementation of np.sum for DiagonalArray objects"
... return arr._i * arr._N
...
>>> @implements(np.mean)
... def sum(a):
... "Implementation of np.mean for DiagonalArray objects"
... return arr._i / arr._N
...
>>> arr = DiagonalArray(5, 1)
>>> np.sum(arr)
5
>>> np.mean(arr)
0.2
If the user tries to use any numpy functions not included in
HANDLED_FUNCTIONS
, a TypeError
will be raised by numpy, indicating that
this operation is not supported. For example, concatenating two
DiagonalArrays
does not produce another diagonal array, so it is not
supported.
>>> np.concatenate([arr, arr])
TypeError: no implementation found for 'numpy.concatenate' on types that implement __array_function__: [<class '__main__.DiagonalArray'>]
Additionally, our implementations of sum
and mean
do not accept the
optional arguments that numpy’s implementation does.
>>> np.sum(arr, axis=0)
TypeError: sum() got an unexpected keyword argument 'axis'
The user always has the option of converting to a normal numpy.ndarray
with
numpy.asarray
and using standard numpy from there.
>>> np.concatenate([np.asarray(arr), np.asarray(arr)])
array([[1., 0., 0., 0., 0.],
[0., 1., 0., 0., 0.],
[0., 0., 1., 0., 0.],
[0., 0., 0., 1., 0.],
[0., 0., 0., 0., 1.],
[1., 0., 0., 0., 0.],
[0., 1., 0., 0., 0.],
[0., 0., 1., 0., 0.],
[0., 0., 0., 1., 0.],
[0., 0., 0., 0., 1.]])
Refer to the dask source code and cupy source code for more fully-worked examples of custom array containers.
See also NEP 18.