oracular (3) CPS::Functional.3pm.gz
NAME
"CPS::Functional" - functional utilities in Continuation-Passing Style
SYNOPSIS
use CPS::Functional qw( kmap );
use Example::HTTP::Client qw( k_get_http );
use List::Util qw( sum );
my @URLs = (
"http://www.foo.com",
"http://www.bar.com",
);
kmap( \@URLs,
sub {
my ( $item, $kret ) = @_;
k_get_http( uri => $item, on_response => sub {
my ( $response ) = @_;
$kret->( $response->content_length );
} );
},
sub {
my ( @sizes ) = @_;
say "Total length of all URLs: " . sum(@sizes);
},
);
DESCRIPTION
This module provides CPS versions of data-flow functionals, such as Perl's "map" and "grep", where
function bodies are invoked and expected to return data, which the functional manages. They are built on
top of the control-flow functionals provided by the "CPS" module itself.
FUNCTIONS
kmap( \@items, \&body, $k )
CPS version of perl's "map" statement. Calls the "body" code once for each element in @items, capturing
the list of values the body passes into its continuation. When the items are exhausted, $k is invoked and
passed a list of all the collected values.
$body->( $item, $kret )
$kret->( @items_out )
$k->( @all_items_out )
kgrep( \@items, \&body, $k )
CPS version of perl's "grep" statement. Calls the "body" code once for each element in @items, capturing
those elements where the body's continuation was invoked with a true value. When the items are exhausted,
$k is invoked and passed a list of the subset of @items which were selected.
$body->( $item, $kret )
$kret->( $select )
$k->( @chosen_items )
kfoldl( \@items, \&body, $k )
CPS version of "List::Util::reduce", which collapses (or "folds") a list of values down to a single
scalar, by successively accumulating values together.
If @items is empty, invokes $k immediately, passing in "undef".
If @items contains a single value, invokes $k immediately, passing in just that single value.
Otherwise, initialises an accumulator variable with the first value in @items, then for each additional
item, invokes the "body" passing in the accumulator and the next item, storing back into the accumulator
the value that "body" passed to its continuation. When the @items are exhausted, it invokes $k, passing
in the final value of the accumulator.
$body->( $acc, $item, $kret )
$kret->( $new_acc )
$k->( $final_acc )
Technically, this is not a true Scheme/Haskell-style "foldl", as it does not take an initial value. (It
is what Haskell calls "foldl1".) However, if such an initial value is required, this can be provided by
kfoldl( [ $initial, @items ], \&body, $k )
kfoldr( \@items, \&body, $k )
A right-associative version of "kfoldl()". Where "kfoldl()" starts with the first two elements in @items
and works forward, "kfoldr()" starts with the last two and works backward.
$body->( $item, $acc, $kret )
$kret->( $new_acc )
$k->( $final_acc )
As before, an initial value can be provided by modifying the @items array, though note it has to be last
this time:
kfoldr( [ @items, $initial ], \&body, $k )
kunfold( $seed, \&body, $k )
An inverse operation to "kfoldl()"; turns a single scalar into a list of items. Repeatedly calls the
"body" code, capturing the values it returns, until it indicates the end of the loop, then invoke $k with
the collected values.
$body->( $seed, $kmore, $kdone )
$kmore->( $new_seed, @items )
$kdone->( @items )
$k->( @all_items )
With each iteration, the "body" is invoked and passed the current $seed value and two continuations,
$kmore and $kdone. If $kmore is invoked, the passed items, if any, are appended to the eventual result
list. The "body" is then re-invoked with the new $seed value. If $klast is invoked, the passed items, if
any, are appended to the return list, then the entire list is passed to $k.
EXAMPLES
The following aren't necessarily examples of code which would be found in real programs, but instead,
demonstrations of how to use the above functions as ways of controlling program flow.
Without dragging in large amount of detail on an asynchronous or event-driven framework, it is difficult
to give a useful example of behaviour that CPS allows that couldn't be done just as easily without.
Nevertheless, I hope the following examples will be useful to demonstrate use of the above functions, in
a way which hints at their use in a real program.
Implementing "join()" using "kfoldl()"
use CPS::Functional qw( kfoldl );
my @words = qw( My message here );
kfoldl(
\@words,
sub {
my ( $left, $right, $k ) = @_;
$k->( "$left $right" );
},
sub {
my ( $str ) = @_;
print "Joined up words: $str\n";
}
);
Implementing "split()" using "kunfold()"
The following program illustrates the way that "kunfold()" can split a string, in a reverse way to the
way "kfoldl()" can join it.
use CPS::Functional qw( kunfold );
my $str = "My message here";
kunfold(
$str,
sub {
my ( $s, $kmore, $kdone ) = @_;
if( $s =~ s/^(.*?) // ) {
return $kmore->( $s, $1 );
}
else {
return $kdone->( $s );
}
},
sub {
my @words = @_;
print "Words in message:\n";
print "$_\n" for @words;
}
);
Generating Prime Numbers
While the design of "kunfold()" is symmetric to "kfoldl()", the seed value doesn't have to be
successively broken apart into pieces. Another valid use for it may be storing intermediate values in
computation, such as in this example, storing a list of known primes, to help generate the next one:
use CPS::Functional qw( kunfold );
kunfold(
[ 2, 3 ],
sub {
my ( $vals, $kmore, $kdone ) = @_;
return $kdone->() if @$vals >= 50;
PRIME: for( my $n = $vals->[-1] + 2; ; $n += 2 ) {
$n % $_ == 0 and next PRIME for @$vals;
push @$vals, $n;
return $kmore->( $vals, $n );
}
},
sub {
my @primes = ( 2, 3, @_ );
print "Primes are @primes\n";
}
);
Forward-reading Program Flow
One side benefit of the CPS control-flow methods which is unassociated with asynchronous operation, is
that the flow of data reads in a more natural left-to-right direction, instead of the right-to-left flow
in functional style. Compare
sub square { $_ * $_ }
sub add { $a + $b }
print reduce( \&add, map( square, primes(10) ) );
(because "map" is a language builtin but "reduce" is a function with "(&)" prototype, it has a different
way to pass in the named functions)
with
my $ksquare = liftk { $_[0] * $_[0] };
my $kadd = liftk { $_[0] + $_[1] };
kprimes 10, sub {
kmap \@_, $ksquare, sub {
kfoldl \@_, $kadd, sub {
print $_[0];
}
}
};
This translates roughly to a functional vs imperative way to describe the problem:
Print the sum of the squares of the first 10 primes.
Take the first 10 primes. Square them. Sum them. Print.
Admittedly the closure creation somewhat clouds the point in this small example, but in a larger example,
the real problem-solving logic would be larger, and stand out more clearly against the background
boilerplate.
SEE ALSO
• CPS - manage flow of control in Continuation-Passing Style
AUTHOR
Paul Evans <leonerd@leonerd.org.uk>