As a general rule, functions should already be written with matrix arguments in mind and should consider whole matrix operations in a vectorized manner. Sometimes, writing functions in this way appears difficult or impossible for various reasons. For those situations, Octave provides facilities for applying a function to each element of an array, cell, or struct.
B = arrayfun (fcn, A) ¶B = arrayfun (fcn, A1, A2, …) ¶[B1, B2, …] = arrayfun (fcn, A, …) ¶B = arrayfun (…, "UniformOutput", val) ¶B = arrayfun (…, "ErrorHandler", errfcn) ¶Execute a function on each element of an array.
This is useful for functions that do not accept array arguments. If the function does accept array arguments it is better to call the function directly.
The first input argument fcn can be a string, a function handle, an
inline function, or an anonymous function. The input argument A can be a
logical array, a numeric array, a string array, a structure array, or a cell
array. arrayfun passes all elements of A individually to the
function fcn and collects the results. The equivalent pseudo-code is
cls = class (fcn (A(1)); B = zeros (size (A), cls); for i = 1:numel (A) B(i) = fcn (A(i)) endfor
The named function can also take more than two input arguments, with the input arguments given as third input argument A2, fourth input argument A2, … If given more than one array input argument then all input arguments must have the same sizes. For example:
arrayfun (@atan2, [1, 0], [0, 1])
⇒ [ 1.57080 0.00000 ]
If the parameter val after a further string input argument
"UniformOutput" is set true (the default), then the named
function fcn must return a single element which then will be concatenated
into the return value and is of type matrix. Otherwise, if that parameter is
set to false, then the outputs are concatenated in a cell array. For
example:
arrayfun (@(x,y) x:y, "abc", "def", "UniformOutput", false)
⇒
{
[1,1] = abcd
[1,2] = bcde
[1,3] = cdef
}
If more than one output arguments are given then the named function must return the number of return values that also are expected, for example:
[A, B, C] = arrayfun (@find, [10; 0], "UniformOutput", false)
⇒
A =
{
[1,1] = 1
[2,1] = [](0x0)
}
B =
{
[1,1] = 1
[2,1] = [](0x0)
}
C =
{
[1,1] = 10
[2,1] = [](0x0)
}
If the parameter errfcn after a further string input argument
"ErrorHandler" is another string, a function handle, an inline
function, or an anonymous function, then errfcn defines a function to
call in the case that fcn generates an error. The definition of the
function must be of the form
function [...] = errfcn (s, ...)
where there is an additional input argument to errfcn relative to
fcn, given by s. This is a structure with the elements
"identifier", "message", and "index" giving,
respectively, the error identifier, the error message, and the index of the
array elements that caused the error. The size of the output argument of
errfcn must have the same size as the output argument of fcn,
otherwise a real error is thrown. For example:
function y = ferr (s, x), y = "MyString"; endfunction
arrayfun (@str2num, [1234],
"UniformOutput", false, "ErrorHandler", @ferr)
⇒
{
[1,1] = MyString
}
y = spfun (f, S) ¶Compute f (S) for the nonzero elements of S.
The input function f is applied only to the nonzero elements of the input matrix S which is typically sparse. The function f can be passed as a string, function handle, or inline function.
The output y is a sparse matrix with the same sparsity structure as
the input S. spfun preserves sparsity structure which is
different than simply applying the function f to the sparse matrix
S when f (0) != 0.
Example
Sparsity preserving spfun versus normal function application
S = pi * speye (2,2) S = Compressed Column Sparse (rows = 2, cols = 2, nnz = 2 [50%]) (1, 1) -> 3.1416 (2, 2) -> 3.1416 y = spfun (@cos, S) y = Compressed Column Sparse (rows = 2, cols = 2, nnz = 2 [50%]) (1, 1) -> -1 (2, 2) -> -1
y = cos (S) y = Compressed Column Sparse (rows = 2, cols = 2, nnz = 4 [100%]) (1, 1) -> -1 (2, 1) -> 1 (1, 2) -> 1 (2, 2) -> -1
A = cellfun ("fcn", C) ¶A = cellfun ("size", C, k) ¶A = cellfun ("isclass", C, class) ¶A = cellfun (@fcn, C) ¶A = cellfun (fcn, C) ¶A = cellfun (fcn, C1, C2, …) ¶[A1, A2, …] = cellfun (…) ¶A = cellfun (…, "ErrorHandler", errfcn) ¶A = cellfun (…, "UniformOutput", val) ¶Evaluate the function named "fcn" on the elements of the cell array C.
Elements in C are passed on to the named function individually. The function fcn can be one of the functions
isemptyReturn 1 for empty elements.
islogicalReturn 1 for logical elements.
isnumericReturn 1 for numeric elements.
isrealReturn 1 for real elements.
lengthReturn a vector of the lengths of cell elements.
ndimsReturn the number of dimensions of each element.
numelprodofsizeReturn the number of elements contained within each cell element. The number is the product of the dimensions of the object at each cell element.
sizeReturn the size along the k-th dimension.
isclassReturn 1 for elements of class.
Additionally, cellfun accepts an arbitrary function fcn in the
form of an inline function, function handle, or the name of a function (in a
character string). The function can take one or more arguments, with the
inputs arguments given by C1, C2, etc. For example:
cellfun ("atan2", {1, 0}, {0, 1})
⇒ [ 1.57080 0.00000 ]
The number of output arguments of cellfun matches the number of output
arguments of the function and can be greater than one. When there are multiple
outputs of the function they will be collected into the output arguments of
cellfun like this:
function [a, b] = twoouts (x)
a = x;
b = x*x;
endfunction
[aa, bb] = cellfun (@twoouts, {1, 2, 3})
⇒
aa =
1 2 3
bb =
1 4 9
Note that, per default, the output argument(s) are arrays of the same size as the input arguments. Input arguments that are singleton (1x1) cells will be automatically expanded to the size of the other arguments.
If the parameter "UniformOutput" is set to true (the default), then the
function must return scalars which will be concatenated into the return
array(s). If "UniformOutput" is false, the outputs are concatenated
into a cell array (or cell arrays). For example:
cellfun ("lower", {"Foo", "Bar", "FooBar"},
"UniformOutput", false)
⇒ {"foo", "bar", "foobar"}
Given the parameter "ErrorHandler", then errfcn defines a
function to call in case fcn generates an error. The form of the
function is
function [...] = errfcn (s, ...)
where there is an additional input argument to errfcn relative to
fcn, given by s. This is a structure with the elements
"identifier", "message", and "index" giving
respectively the error identifier, the error message, and the index into the
input arguments of the element that caused the error. For example:
function y = foo (s, x), y = NaN; endfunction
cellfun ("factorial", {-1,2}, "ErrorHandler", @foo)
⇒ [NaN 2]
Use cellfun intelligently. The cellfun function is a useful tool
for avoiding loops. It is often used with anonymous function handles; however,
calling an anonymous function involves an overhead quite comparable to the
overhead of an m-file function. Passing a handle to a built-in function is
faster, because the interpreter is not involved in the internal loop. For
example:
C = {...}
v = cellfun (@(x) det (x), C); # compute determinants
v = cellfun (@det, C); # 40% faster
A = structfun (fcn, S) ¶A = structfun (…, "ErrorHandler", errfcn) ¶A = structfun (…, "UniformOutput", val) ¶[A, B, …] = structfun (…) ¶Evaluate the function named name on the fields of the structure S. The fields of S are passed to the function fcn individually.
structfun accepts an arbitrary function fcn in the form of an
inline function, function handle, or the name of a function (in a character
string). In the case of a character string argument, the function must
accept a single argument named x, and it must return a string value.
If the function returns more than one argument, they are returned as
separate output variables.
If the parameter "UniformOutput" is set to true (the default), then
the function must return a single element which will be concatenated into
the return value. If "UniformOutput" is false, the outputs are
placed into a structure with the same fieldnames as the input structure.
s.name1 = "John Smith";
s.name2 = "Jill Jones";
structfun (@(x) regexp (x, '(\w+)$', "matches"){1}, s,
"UniformOutput", false)
⇒ scalar structure containing the fields:
name1 = Smith
name2 = Jones
Given the parameter "ErrorHandler", errfcn defines a function
to call in case fcn generates an error. The form of the function is
function [...] = errfcn (se, ...)
where there is an additional input argument to errfcn relative to
fcn, given by se. This is a structure with the
elements "identifier", "message" and "index",
giving respectively the error identifier, the error message, and the index
into the input arguments of the element that caused the error. For an
example on how to use an error handler, see cellfun.
Consistent with earlier advice, seek to use Octave built-in functions whenever
possible for the best performance. This advice applies especially to the four
functions above. For example, when adding two arrays together
element-by-element one could use a handle to the built-in addition function
@plus or define an anonymous function @(x,y) x + y. But, the
anonymous function is 60% slower than the first method.
See Operator Overloading, for a list of basic functions which might be used
in place of anonymous ones.