# How can I create all subsets of size smaller than n in Perl?

I have a set of sets. I want to create all sets that take at most one element from each original set. For example, if my original set of sets is `((x,y),(A),(1,2))` then the solutions are:

``````(x)
(y)
(A)
(1)
(2)
(x,A)
(x,1)
(x,2)
(y,A)
(y,A)
(y,1)
(y,2)
(A,1)
(A,2)
(x,A,1)
(x,A,2)
(y,A,1)
(y,A,2)
``````

I use the following code I have written to recursively calculate this:

``````# gets an array of arrays (aoa)
# returns an array of arrays with all subsets where zero or one element is
# taken from each array, e.g. in = [[a,b],[5],[X,Y,Z]], out =
# [[],[a],[b],[5],[X],[Y],[Z],[a,5],[b,5],[a,X],[a,Y],...,[b,5,Y],[b,5,Z]]
# note the order of elelemnts in each arry is immaterial (an array is
# considered an unordered set)
sub sets_aoa_to_subsets_aoa {
my \$aoa = shift // confess;

if ( scalar( @{\$aoa} ) == 0 ) {
return [ [] ];
}

my \$a           = shift @{\$aoa};
my \$subsets_aoa = sets_aoa_to_subsets_aoa(\$aoa);
my @new_subsets = ();
foreach my \$subset_a ( @{\$subsets_aoa} ) {

# leave subset as-is
push @new_subsets, \$subset_a;

# add one element from \$a
foreach my \$e ( @{\$a} ) {
push @new_subsets, [ \$e, @{\$subset_a} ];
}
}
return \@new_subsets;

}
``````

however, I would like to add a limit on the size of the subset. For example, if I set `max_size=2` then the last four solutions will be ignored. I can't simply generate all solutions then filter those who are too large, since sometimes I have more then 100 sets each with 2-3 elements, and 2^100 is not a nice number to handle, especially when I only want subsets of size 5 or less.

-
I’m not yet completely certain, but I do believe this can be elegantly solved with a regular expression. It may take me a moment to work it out, though. –  tchrist Nov 7 '10 at 16:43
You realize that 100 sets of 2-3 elements and size 5 will give you around 10 billion results? What is the underlying problem that leads you to want to do this set generation? There may be a better way... –  ysth Nov 7 '10 at 17:10

As I suspected, a regex works for this.

## Specific Solution

Here’s the specific solution to the question precisely as posed. There are 80 answers.

``````my %seen;

"xy=a=12" =~ m{
[^=]* (x|y)* [^=]*
=
[^=]* (a)*   [^=]*
=
[^=]* (1|2)* [^=]*

(?{
my \$size = grep { length } \$1, \$2, \$3;
print "<\$1> <\$2> <\$3>\n"
if \$size >= 1 &&
\$size <= 2 &&
! \$seen{\$1,\$2,\$3}++;
})
(*FAIL)
}x;
``````

Run that piped to `cat -n` and you’ll see your 80 answers.

Of course, you’ll want something that’s generalized and extensible so that you can apply it to your situation of a hundred sets. It always takes longer to craft a general solution than a specific one, so I’ll work on that generalization and get back to you as soon as it looks pretty.

## General Solution

Here’s the general solution; it’s hardly my prettiest piece of work, but it does work:

``````#!/usr/bin/perl

use 5.010;
use strict;
use warnings;

our(\$MIN_PICK, \$MAX_PICK) = (1, 2);

our @List_of_Sets = (
[ qw[ x y ] ],
[ qw[ a   ] ],
[ qw[ 1 2 ] ],
);

sub dequeue(\$\$) {
return \$body;
}

################################

my \$gunk     = " (?&gunk) ";
my \$alter_rx = join("\n\t(?&post)\n" => map {
" \$gunk ( "
. join(" | " => map { quotemeta } @\$_)
. " ) * \$gunk "
} @List_of_Sets);
##print "ALTER_RX <\n\$alter_rx\n>\n";

my \$string = join(" = ", map { join(" ", @\$_) } @List_of_Sets);
##print "STRING: \$string\n";

my \$numbers_list    = join(", " => map {  '\$' . \$_        } 1 .. @List_of_Sets);
my \$numbers_bracket = join(" "  => map { '<\$' . \$_  . '>' } 1 .. @List_of_Sets);

my \$print_statement = dequeue "|QQ|" => <<"PRINT_STATEMENT";

|QQ|
|QQ|    (?{
|QQ|        no warnings qw(uninitialized);
|QQ|        my \\$size = grep { length } \$numbers_list;
|QQ|        print "\$numbers_bracket\\n"
|QQ|            if \\$size >= \$MIN_PICK &&
|QQ|               \\$size <= \$MAX_PICK &&
|QQ|             ! \\$seen{\$numbers_list}++;
|QQ|    })
|QQ|

PRINT_STATEMENT
## print "PRINT \$print_statement\n";

my \$search_rx = do {
use re "eval";
my %seen;
qr{
^
\$alter_rx
\$

\$print_statement

(*FAIL)

(?(DEFINE)
(?<post>   =    )
(?<gunk> [^=] * )
)
}x;
};
## print qq(SEARCH:\n"\$string" =~ \$search_rx\n);

# run, run, run!!
\$string =~ \$search_rx;
``````

I am somewhat concerned with the number of possibilities you expect to pull out of this. It may be that you should put this process I’ve outlined above on the other end of a pipe so that you can read from it however much you want and then hang up the phone, so to speak, when you’ve had your fill.

I realize this is a rather unusual solution; my code often is. :)

I just figure you might as well make the exhaustively permutational nature of regex backtracking do the work for you.

Perhaps others will pull out `Some::Abstruse::Module` to do the job for you. You’ll just have to weigh which you prefer.

EDIT: Improved legibility, handled duplicates and extra min/max criteria.

-
“There are 80 answers”? I count 14... Looks like your solution counts a lot of duplicates ... and still manages to miss those with size one. –  mscha Nov 7 '10 at 18:49
I didn’t bother to trim duplicates; it’s trivial. If size 2 is not wanted, merely change `2 ==` into whatever is wanted. That’s why it was written that way. The problem wasn’t completely well-specified, so I wrote it in an open-ended way, suitable for adaptation. –  tchrist Nov 7 '10 at 19:03
@mscha: Your concerns have been addressed. –  tchrist Nov 7 '10 at 19:46
Better. :-) Downvote removed. (You still might want to remove the references to "80 solutions".) –  mscha Nov 7 '10 at 20:05
+1 interesting approach. thanks! –  David B Nov 12 '10 at 7:56

Also a recursive solution, but passing the subset-built-sofar along, so you can stop as soon as you reach the maximum size.

``````#!/opt/perl/bin/perl

use strict;
use warnings;
use 5.010;

sub subsets
{
my (\$sets, \$maxSize, \$subset) = @_;
\$subset //= [ ];

# If we already have \$maxSize elements, we're done
return (\$subset) if @\$subset == \$maxSize;

# If we have no sets left to pick from, we're done
return (\$subset) if !@\$sets;

# Consider the next set
my @remainingSets = @\$sets;
my \$nextSet = shift(@remainingSets);

# We can choose either 0 or 1 element from this set, continue with the rest
return (subsets(\@remainingSets, \$maxSize, \$subset),
map { subsets(\@remainingSets, \$maxSize, [@\$subset, \$_]) }
@\$nextSet);
}

my \$sets = [ [qw(x y)], [qw(A)], [qw(1 2)] ];
my @subsets = subsets(\$sets, 2);

foreach my \$subset (@subsets) {
say '(', join(', ', @\$subset), ')';
}
``````
-
+1 thanks mscha! –  David B Nov 12 '10 at 7:55

you could create a "state variable" which would track the number of calls to sets_aoa_to_subsets_aoa and then check for that in your treminal condition:

``````{
my \$count=0;
sub sets_aoa_to_subsets_aoa {
\$count++;
my (\$aoa,\$number_of_calls) = @_ // confess;
if ( (scalar( @{\$aoa} ) == 0) or (\$count == \$number_or_calls)) {
return [ [] ];
}
......
}
}
``````
-
``````    foreach my \$e ( @{\$a} ) {
simply pass down a `\$items_wanted` paramter and skip the highlighted bit of code if `@{\$subset_a} > \$items_wanted`. Since the lines above already generate all of the combinations that don't add additional items, this will work without any further changes.