Generalized Universal Function API
There is a general need for looping over not only functions on scalars but also over functions on vectors (or arrays). This concept is realized in NumPy by generalizing the universal functions (ufuncs). In regular ufuncs, the elementary function is limited to element-by-element operations, whereas the generalized version (gufuncs) supports “sub-array” by “sub-array” operations. The Perl vector library PDL provides a similar functionality and its terms are re-used in the following.
Each generalized ufunc has information associated with it that states
what the “core” dimensionality of the inputs is, as well as the
corresponding dimensionality of the outputs (the element-wise ufuncs
have zero core dimensions). The list of the core dimensions for all
arguments is called the “signature” of a ufunc. For example, the
ufunc numpy.add has signature
(),()->() defining two scalar inputs
and one scalar output.
Another example is the function
inner1d(a, b) with a signature of
(i),(i)->(). This applies the inner product along the last axis of
each input, but keeps the remaining indices intact.
For example, where
a is of shape
(3, 5, N) and
b is of shape
(5, N), this will return an output of shape
The underlying elementary function is called
3 * 5 times. In the
signature, we specify one core dimension
(i) for each input and zero core
() for the output, since it takes two 1-d arrays and
returns a scalar. By using the same name
i, we specify that the two
corresponding dimensions should be of the same size.
The dimensions beyond the core dimensions are called “loop” dimensions. In
the above example, this corresponds to
The signature determines how the dimensions of each input/output array are split into core and loop dimensions:
- Each dimension in the signature is matched to a dimension of the corresponding passed-in array, starting from the end of the shape tuple. These are the core dimensions, and they must be present in the arrays, or an error will be raised.
- Core dimensions assigned to the same label in the signature (e.g. the
(i),(i)->()) must have exactly matching sizes, no broadcasting is performed.
- The core dimensions are removed from all inputs and the remaining dimensions are broadcast together, defining the loop dimensions.
- The shape of each output is determined from the loop dimensions plus the output’s core dimensions
Typically, the size of all core dimensions in an output will be determined by
the size of a core dimension with the same label in an input array. This is
not a requirement, and it is possible to define a signature where a label
comes up for the first time in an output, although some precautions must be
taken when calling such a function. An example would be the function
euclidean_pdist(a), with signature
(n,d)->(p), that given an array of
d-dimensional vectors, computes all unique pairwise Euclidean
distances among them. The output dimension
p must therefore be equal to
n * (n - 1) / 2, but it is the caller’s responsibility to pass in an
output array of the right size. If the size of a core dimension of an output
cannot be determined from a passed in input or output array, an error will be
Note: Prior to NumPy 1.10.0, less strict checks were in place: missing core dimensions were created by prepending 1’s to the shape as necessary, core dimensions with the same label were broadcast together, and undetermined dimensions were created with size 1.
Each ufunc consists of an elementary function that performs the most basic operation on the smallest portion of array arguments (e.g. adding two numbers is the most basic operation in adding two arrays). The ufunc applies the elementary function multiple times on different parts of the arrays. The input/output of elementary functions can be vectors; e.g., the elementary function of inner1d takes two vectors as input.
A signature is a string describing the input/output dimensions of the elementary function of a ufunc. See section below for more details.
The dimensionality of each input/output of an elementary function is defined by its core dimensions (zero core dimensions correspond to a scalar input/output). The core dimensions are mapped to the last dimensions of the input/output arrays.
A dimension name represents a core dimension in the signature. Different dimensions may share a name, indicating that they are of the same size.
A dimension index is an integer representing a dimension name. It enumerates the dimension names according to the order of the first occurrence of each name in the signature.
Details of Signature
The signature defines “core” dimensionality of input and output variables, and thereby also defines the contraction of the dimensions. The signature is represented by a string of the following format:
- Core dimensions of each input or output array are represented by a
list of dimension names in parentheses,
(i_1,...,i_N); a scalar input/output is denoted by
(). Instead of
i_2, etc, one can use any valid Python variable name.
- Dimension lists for different arguments are separated by
",". Input/output arguments are separated by
- If one uses the same dimension name in multiple locations, this enforces the same size of the corresponding dimensions.
The formal syntax of signatures is as follows:
<Signature> ::= <Input arguments> "->" <Output arguments> <Input arguments> ::= <Argument list> <Output arguments> ::= <Argument list> <Argument list> ::= nil | <Argument> | <Argument> "," <Argument list> <Argument> ::= "(" <Core dimension list> ")" <Core dimension list> ::= nil | <Core dimension> | <Core dimension> "," <Core dimension list> <Core dimension> ::= <Dimension name> <Dimension modifier> <Dimension name> ::= valid Python variable name | valid integer <Dimension modifier> ::= nil | "?"
- All quotes are for clarity.
- Unmodified core dimensions that share the same name must have the same size. Each dimension name typically corresponds to one level of looping in the elementary function’s implementation.
- White spaces are ignored.
- An integer as a dimension name freezes that dimension to the value.
- If the name is suffixed with the “?” modifier, the dimension is a core dimension only if it exists on all inputs and outputs that share it; otherwise it is ignored (and replaced by a dimension of size 1 for the elementary function).
Here are some examples of signatures:
|matmul||(m?,n),(n,p?)->(m?,p?)||combination of the four above|
|outer_inner||(i,t),(j,t)->(i,j)||inner over the last dimension, outer over the second to last, and loop/broadcast over the rest.|
|cross1d||(3),(3)->(3)||cross product where the last dimension is frozen and must be 3|
The last is an instance of freezing a core dimension and can be used to improve ufunc performance
C-API for implementing Elementary Functions
The current interface remains unchanged, and
can still be used to implement (specialized) ufuncs, consisting of
scalar elementary functions.
One can use
PyUFunc_FromFuncAndDataAndSignature to declare a more
general ufunc. The argument list is the same as
PyUFunc_FromFuncAndData, with an additional argument specifying the
signature as C string.
Furthermore, the callback function is of the same type as before,
void (*foo)(char **args, intp *dimensions, intp *steps, void *func).
args is a list of length
the data of all input/output arguments. For a scalar elementary
steps is also of length
nargs, denoting the strides used
for the arguments.
dimensions is a pointer to a single integer
defining the size of the axis to be looped over.
For a non-trivial signature,
dimensions will also contain the sizes
of the core dimensions as well, starting at the second entry. Only
one size is provided for each unique dimension name and the sizes are
given according to the first occurrence of a dimension name in the
nargs elements of
steps remain the same as for scalar
ufuncs. The following elements contain the strides of all core
dimensions for all arguments in order.
For example, consider a ufunc with signature
args will contain three pointers to the data of the
dimensions will be
[N, I, J] to define the size of
N of the loop and the sizes
for the core dimensions
steps will be
[a_N, b_N, c_N, a_i, a_j, b_i], containing all necessary strides.