/usr/share/octave/packages/interval-2.1.0/@infsup/times.m is in octave-interval 2.1.0-2.
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##
## This program is free software; you can redistribute it and/or modify
## it under the terms of the GNU General Public License as published by
## the Free Software Foundation; either version 3 of the License, or
## (at your option) any later version.
##
## This program is distributed in the hope that it will be useful,
## but WITHOUT ANY WARRANTY; without even the implied warranty of
## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
## GNU General Public License for more details.
##
## You should have received a copy of the GNU General Public License
## along with this program; if not, see <http://www.gnu.org/licenses/>.
## -*- texinfo -*-
## @documentencoding UTF-8
## @defop Method {@@infsup} times (@var{X}, @var{Y})
## @defopx Operator {@@infsup} {@var{X} .* @var{Y}}
##
## Multiply all numbers of interval @var{X} by all numbers of @var{Y}.
##
## Accuracy: The result is a tight enclosure.
##
## @example
## @group
## x = infsup (2, 3);
## y = infsup (1, 2);
## x .* y
## @result{} ans = [2, 6]
## @end group
## @end example
## @seealso{@@infsup/rdivide}
## @end defop
## Author: Oliver Heimlich
## Keywords: interval
## Created: 2014-09-30
function x = times (x, y)
if (nargin ~= 2)
print_usage ();
return
endif
if (not (isa (x, "infsup")))
x = infsup (x);
endif
if (not (isa (y, "infsup")))
y = infsup (y);
elseif (isa (y, "infsupdec"))
## Workaround for bug #42735
result = times (x, y);
return
endif
## At least one case of interval multiplication is complicated: when zero is an
## inner point of both interval factors. In all other cases it would suffice
## to compute a single product for each product boundary.
##
## It is not significandly faster to do a case by case analysis in order to
## save some calls to the times function with directed rounding. Therefore, we
## simply compute the product for each pair of boundaries where the min/max
## could be located.
l = min (min (min (...
mpfr_function_d ('times', -inf, x.inf, y.inf), ...
mpfr_function_d ('times', -inf, x.inf, y.sup)), ...
mpfr_function_d ('times', -inf, x.sup, y.inf)), ...
mpfr_function_d ('times', -inf, x.sup, y.sup));
u = max (max (max (...
mpfr_function_d ('times', +inf, x.inf, y.inf), ...
mpfr_function_d ('times', +inf, x.inf, y.sup)), ...
mpfr_function_d ('times', +inf, x.sup, y.inf)), ...
mpfr_function_d ('times', +inf, x.sup, y.sup));
## [0] × anything = [0] × [0]
## [Entire] × anything but [0] = [Entire] × [Entire]
## This prevents the cases where 0 × inf would produce NaNs.
entireproduct = isentire (x) | isentire (y);
l(entireproduct) = -inf;
u(entireproduct) = inf;
zeroproduct = (x.inf == 0 & x.sup == 0) | (y.inf == 0 & y.sup == 0);
l(zeroproduct) = -0;
u(zeroproduct) = +0;
emptyresult = isempty (x) | isempty (y);
l(emptyresult) = inf;
u(emptyresult) = -inf;
l(l == 0) = -0;
x.inf = l;
x.sup = u;
endfunction
%!# from the documentation string
%!assert (infsup (2, 3) .* infsup (1, 2) == infsup (2, 6));
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