Provided by: libset-scalar-perl_1.27-1_all bug

NAME

       Set::Scalar - basic set operations

SYNOPSIS

           use Set::Scalar;
           $s = Set::Scalar->new;
           $s->insert('a', 'b');
           $s->delete('b');
           $t = Set::Scalar->new('x', 'y', $z);

DESCRIPTION

   Creating
           $s = Set::Scalar->new;
           $s = Set::Scalar->new(@members);

           $t = $s->clone;
           $t = $s->copy;         # Clone of clone.
           $t = $s->empty_clone;  # Like clone() but with no members.

   Modifying
           $s->insert(@members);
           $s->delete(@members);
           $s->invert(@members);  # Insert if hasn't, delete if has.

           $s->clear;  # Removes all the elements.

       Note that clear() only releases the memory used by the set to be reused by Perl; it will
       not reduce the overall memory use.

   Displaying
           print $s, "\n";

       The display format of a set is the members of the set separated by spaces and enclosed in
       parentheses (), for example:

          my $s = Set::Scalar->new();
          $s->insert("a".."e");
          print $s, "\n";

       will output

          a b c d e

       You can even display recursive sets.

       See "Customising Display" for customising the set display.

   Querying
       Assuming a set $s:

           @members  = $s->members;
           @elements = $s->elements;  # Alias for members.

           @$s  # Overloaded alias for members.

           $size = $s->size;  # The number of members.

           $s->has($m)        # Return true if has that member.
           $s->contains($m)   # Alias for has().

           if ($s->has($member)) { ... }

           $s->member($m)     # Returns the member if has that member.
           $s->element($m)    # Alias for member.

           $s->is_null        # Returns true if the set is empty.
           $s->is_empty       # Alias for is_null.

           $s->is_universal   # Returns true if the set is universal.

           $s->null           # The null set.
           $s->empty          # Alias for null.
           $s->universe       # The universe of the set.

   Deriving
           $u = $s->union($t);
           $i = $s->intersection($t);
           $d = $s->difference($t);
           $e = $s->symmetric_difference($t);
           $v = $s->unique($t);
           $c = $s->complement;

       These methods have operator overloads:

           $u = $s + $t;  # union
           $i = $s * $t;  # intersection
           $d = $s - $t;  # difference
           $e = $s % $t;  # symmetric_difference
           $v = $s / $t;  # unique
           $c = -$s;      # complement

       Both the "symmetric_difference" and "unique" are symmetric on all their arguments.  For
       two sets they are identical but for more than two sets beware: "symmetric_difference"
       returns true for elements that are in an odd number (1, 3, 5, ...) of sets, "unique"
       returns true for elements that are in one set.

       Some examples of the various set differences below (the _ is just used to align the
       elements):

           set or difference                   value

           $a                                  (a b c d e _ _ _ _ _)
           $b                                  (_ _ _ c d e f g _ _)
           $c                                  (_ _ _ _ _ e f g h i)

           $a->difference($b)                  (a b _ _ _ _ _ _ _ _)
           $a->symmetric_difference($b)        (a b _ _ _ _ f g _ _)
           $a->unique($b)                      (a b _ _ _ _ f g _ _)

           $b->difference($a)                  (_ _ _ _ _ _ f g _ _)
           $b->symmetric_difference($a)        (a b _ _ _ _ f g _ _)
           $b->unique($a)                      (a b _ _ _ _ f g _ _)

           $a->difference($b, $c)              (a b _ _ _ _ _ _ _ _)
           $a->symmetric_difference($b, $c)    (a b _ _ e _ _ _ h i)
           $a->unique($b, $c)                  (a b _ _ _ _ _ _ h i)

   Comparing
           $eq = $s->is_equal($t);
           $dj = $s->is_disjoint($t);
           $pi = $s->is_properly_intersecting($t);
           $ps = $s->is_proper_subset($t);
           $pS = $s->is_proper_superset($t);
           $is = $s->is_subset($t);
           $iS = $s->is_superset($t);

           $cmp = $s->compare($t);

       The "compare" method returns a string from the following list: "equal", "disjoint",
       "proper subset", "proper superset", "proper intersect", and in future (once I get around
       implementing it), "disjoint universes".

       These methods have operator overloads:

           $eq = $s == $t;  # is_equal
           $dj = $s != $t;  # is_disjoint
           # No operator overload for is_properly_intersecting.
           $ps = $s < $t;   # is_proper_subset
           $pS = $s > $t;   # is_proper_superset
           $is = $s <= $t;  # is_subset
           $iS = $s >= $t;  # is_superset

           $cmp = $s <=> $t;

   Boolean contexts
       In Boolean contexts such as

           if ($set) { ... }
           while ($set1 && $set2) { ... }

       the size of the $set is tested, so empty sets test as false, and non-empty sets as true.

   Iterating
           while (defined(my $e = $s->each)) { ... }

       This is more memory-friendly than

           for my $e ($s->elements) { ... }

       which would first construct the full list of elements and then walk through it: the
       "$s->each" handles one element at a time.

       Analogously to using normal "each(%hash)" in scalar context, using "$s->each" has the
       following caveats:

       •   The elements are returned in (apparently) random order.  So don't expect any
           particular order.

       •   When no more elements remain "undef" is returned.  Since you may one day have elements
           named 0 don't test just like this

               while (my $e = $s->each) { ... }           # WRONG!

           but instead like this

               while (defined(my $e = $s->each)) { ... }  # Right.

           (An "undef" as a set element doesn't really work, you get "".)

       •   There is one iterator per one set which is shared by many element-accessing
           interfaces-- using the following will reset the iterator: "elements()", "insert()",
           "members()", "size()", "unique()".  "insert()" causes the iterator of the set being
           inserted (not the set being the target of insertion) becoming reset.  "unique()"
           causes the iterators of all the participant sets becoming reset.  The iterator getting
           reset most probably causes an endless loop. So avoid doing that.

           For "delete()" the story is a little bit more complex: it depends on what element you
           are deleting and on the version of Perl.  On modern Perls you can safely delete the
           element you just deleted.  But deleting random elements can affect the iterator, so
           beware.

       •   Modifying the set during the iteration may cause elements to be missed or duplicated,
           or in the worst case, an endless loop; so don't do that, either.

   Cartesian Product and Power Set
       •   Cartesian product is a product of two or more sets.  For two sets, it is the set
           consisting of ordered pairs of members from each set.  For example for the sets

             (a b)
             (c d e)

           The Cartesian product of the above is the set

             ([a, c] [a, d] [a, e] [b, c] [b, d] [b, e])

           The [,] notation is for the ordered pairs, which sets are not.  This means two things:
           firstly, that [e, b] is not in the above Cartesian product, and secondly, [b, b] is a
           possibility:

             (a b)
             (b c e)

             ([a, b] [a, c] [a, e] [b, b] [b, c] [b, d])

           For example:

             my $a = Set::Scalar->new(1..2);
             my $b = Set::Scalar->new(3..5);
             my $c = $a->cartesian_product($b);  # As an object method.
             my $d = Set::Scalar->cartesian_product($a, $b);  # As a class method.

           The $c and $d will be of the same class as $a.  The members of $c and $c in the above
           will be anonymous arrays (array references), not sets, since sets wouldn't be able to
           represent the ordering or that a member can be present more than once.  Also note that
           since the members of the input sets are unordered, the ordered pairs themselves are
           unlikely to be in any particular order.

           If you don't want to construct the Cartesian product set, you can construct an
           iterator and call it while it returns more members:

              my $iter = Set::Scalar->cartesian_product_iterator($a, $b, $c);
              while (my @m = $iter->()) {
                process(@m);
              }

       •   Power set is the set of all the subsets of a set.  If the set has N members, its power
           set has 2**N members.  For example for the set

               (a b c)

           size 3, its power set is

               (() (a) (b) (c) (a b) (a c) (b c) (a b c))

           size 8.  Note that since the elements of the power set are sets, they are unordered,
           and therefore (b c) is equal to (c b).  For example:

               my $a = Set::Scalar->new(1..3);
               my $b = $a->power_set;               # As an object method.
               my $c = Set::Scalar->power_set($a);  # As a class method.

           Even the empty set has a power set, of size one.

           If you don't want to construct the power set, you can construct an iterator and call
           it until it returns no more members:

              my $iter = Set::Scalar->power_set($a);
              my @m;
              do {
                @m = $iter->();
                process(@m);
              } while (@m);

   Customising Display
       If you want to customise the display routine you will have to modify the "as_string"
       callback.  You can modify it either for all sets by using "as_string_callback()" as a
       class method:

           my $class_callback = sub { ... };

           Set::Scalar->as_string_callback($class_callback);

       or for specific sets by using "as_string_callback()" as an object method:

           my $callback = sub  { ... };

           $s1->as_string_callback($callback);
           $s2->as_string_callback($callback);

       The anonymous subroutine gets as its first (and only) argument the set to display as a
       string.  For example to display the set $s as "a-b-c-d-e" instead of "(a b c d e)"

           $s->as_string_callback(sub{join("-",sort $_[0]->elements)});

       If called without an argument, the current callback is returned.

       If called as a class method with undef as the only argument, the original callback (the
       one returning "(a b c d e)") for all the sets is restored, or if called for a single set
       the callback is removed (and the callback for all the sets will be used).

CAVEATS

       The first priority of Set::Scalar is to be a convenient interface to sets.  While not
       designed to be slow or big, neither has it been designed to be fast or compact.

       Using references (or objects) as set members has not been extensively tested.  The desired
       semantics are not always clear: what should happen when the elements behind the references
       change? Especially unclear is what should happen when the objects start having their own
       stringification overloads.

SEE ALSO

       Set::Bag for bags (multisets, counted sets), and Bit::Vector for fast set operations (you
       have to take care of the element name to bit number and back mappings yourself), or
       Set::Infinite for sets of intervals, and many more.  CPAN is your friend.

AUTHOR

       Jarkko Hietaniemi <jhi@iki.fi> David Oswald <davido@cpan.org> is the current maintainer.
       The GitHub repo is at <https://github.com/daoswald/Set-Scalar>

COPYRIGHT AND LICENSE

       Copyright 2001,2002,2003,2004,2005,2007,2009,2013 by Jarkko Hietaniemi

       This library is free software; you can redistribute it and/or modify it under the same
       terms as Perl itself.