이전: Defining Indexing And Indexed Assignment, 상위 문서: Indexing Objects [차례][찾아보기]
Octave’s ubiquitous lazily-copied pass-by-value semantics implies a problem for
performance of user-defined subsasgn methods. Imagine the following
call to subsasgn
ss = substruct ("()", {1});
x = subsasgn (x, ss, 1);
where the corresponding method looking like this:
function x = subsasgn (x, ss, val)
…
x.myfield (ss.subs{1}) = val;
endfunction
The problem is that on entry to the subsasgn method, x is still
referenced from the caller’s scope, which means that the method will first need
to unshare (copy) x and x.myfield before performing the
assignment. Upon completing the call, unless an error occurs, the result is
immediately assigned to x in the caller’s scope, so that the previous
value of x.myfield is forgotten. Hence, the Octave language implies a
copy of N elements (N being the size of x.myfield), where modifying just
a single element would actually suffice. In other words, a constant-time
operation is degraded to linear-time one. This may be a real problem for user
classes that intrinsically store large arrays.
To partially solve the problem Octave uses a special optimization for
user-defined subsasgn methods coded as m-files. When the method gets
called as a result of the built-in assignment syntax (not a direct
subsasgn call as shown above), i.e., x(1) = 1, AND if
the subsasgn method is declared with identical input and output
arguments, as in the example above, then Octave will ignore the copy of
x inside the caller’s scope; therefore, any changes made to x
during the method execution will directly affect the caller’s copy as well.
This allows, for instance, defining a polynomial class where modifying a single
element takes constant time.
It is important to understand the implications that this optimization brings.
Since no extra copy of x will exist in the caller’s scope, it is
solely the callee’s responsibility to not leave x in an invalid
state if an error occurs during the execution. Also, if the method partially
changes x and then errors out, the changes will affect x
in the caller’s scope. Deleting or completely replacing x inside
subsasgn will not do anything, however, only indexed assignments matter.
Since this optimization may change the way code works (especially if badly
written), a built-in variable optimize_subsasgn_calls is provided to
control it. It is on by default. Another way to avoid the optimization is to
declare subsasgn methods with different output and input arguments like this:
function y = subsasgn (x, ss, val) … endfunction
이전: Defining Indexing And Indexed Assignment, 상위 문서: Indexing Objects [차례][찾아보기]