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Each time I have downloaded a new copy of Rakudo Perl 6, I have run the following expression just to get an idea of its current performance:

say [+] 1 .. 100000;

And the speeds have been increasing, but each time, there is a noticeable delay (several seconds) for the calculation. As a comparison, something like this in Perl 5 (or other interpreted languages) returns almost instantly:

use List::Util 'sum';

print sum(1 .. 100000), "\n";

or in Ruby (also nearly instant):

(1 .. 100000).inject(0) {|sum,x| sum+x}

Rewriting the expression as a Perl6 loop ends up being about twice as fast as reducing the range, but it is still a very noticeable delay (more than a second) for the simple calculation:

my $sum;
loop (my $x = 1; $x <= 100000; $x++) {$sum += $x}

So my question is, what aspects of the Perl6 implementation are causing these performance issues? And should this improve with time, or is this overhead an unfortunate side effect of the "everything is an object" model that Perl6 is using?

And lastly, what about the loop construct is faster than the [+] reduction operator? I would think that the loop would result in more total ops than the reduction.


I'd accept both mortiz's and hobbs's answers if I could. That everything is a being handled as a method call more directly answers why [+] is being slow, so that one gets it.

share|improve this question
'[A] loop would result in more total ops than the reduction. ? I would've imagined that folding the list results in more computation because it's transforming the list to a single value. The loop doesn't appear to do that. – Zaid Jun 28 '10 at 20:32
@Zaid => my reasoning (which might be wrong) was that the loop would have 3 high level ops per iteration (the bounds check, the loop increment, and the $sum increment), whereas the reduction operator would be 2 ops (fetch next item from iterator, add to internal accumulator). – Eric Strom Jun 28 '10 at 20:46
One note here is that comparing to List::Util::sum is more than a bit unfair, since that's a special-purpose function. You should probably be comparing with List::Util::reduce { $a + $b } (1 .. 100000). Mind you, that still runs 50 times per second on my box. – darch Jun 28 '10 at 21:39
This is really relevant to your question so I updated my answer with it:… – hobbs Aug 23 '10 at 16:56
up vote 14 down vote accepted

Another thing you have to understand about the lack of optimization is that it's compounded. A large portion of Rakudo is written in Perl 6. So for example the [+] operator is implemented by the method Any.reduce (called with $expression set to &infix:<+>), which has as its inner loop

for @.list {
    if (@args == $arity) {
        my $res = $expression.(@args[0], @args[1]);
        @args = ($res);

in other words, a pure-perl implementation of reduce, which itself is being run by Rakudo. So not only is the code you can see not getting optimized, the code that you don't see that's making your code run is also not getting optimized. Even instances of the + operator are actually method calls, since although the + operator on Num is implemented by Parrot, there's nothing yet in Rakudo to recognize that you've got two Nums and optimize away the method call, so there's a full dynamic dispatch before Rakudo finds multi sub infix:<+>(Num $a, Num $b) and realizes that all it's really doing is an 'add' opcode. It's a reasonable excuse for being 100-1000x slower than Perl 5 :)

Update 8/23/2010

More information from Jonathan Worthington on the kinds of changes that need to happen with the Perl 6 object model (or at least Rakudo's conception of it) to make things fast while retaining Perl 6's "everything is method calls" nature.

share|improve this answer
+1 everything as a runtime dispatched method call definitely explains why we are seeing this level of performance. Any idea when Rakudo is going to support optimization of Num and Str to be handled by Parrot directly? – Eric Strom Jun 29 '10 at 19:31

There are really various reasons why Rakudo is so slow.

The first and maybe most important reason is that Rakudo doesn't do any optimizations yet. The current goals are more explore new features, and to become more robust. You know, they say "first make it run, then make it right, then make it fast".

The second reason is that parrot doesn't offer any JIT compilation yet, and the garbage collector isn't the fastest. There are plans for a JIT compiler, and people are working on it (the previous one was ripped out because it was i386 only and a maintenance nightmare). There are also thoughts of porting Rakudo to other VMs, but that'll surely wait till after end of July.

In the end, nobody can really tell how fast a complete, well-optimized Perl 6 implementation will be until we have one, but I do expect it to be much better than now.

BTW the case you cited [+] 1..$big_number could be made to run in O(1), because 1..$big_number returns a Range, which is introspectable. So you can use a sum formula for the [+] Range case. Again it's something that could be done, but that hasn't been done yet.

share|improve this answer
+1, these are the kind of details I'm looking for (and from a reputable source no less). detecting [+] Range and using the sum formula would be a great optimization. As it stands right now, does [+] treat Range as an iterator, or does it first convert it to a list and then reduce it? From memory, it seems that increasing $big_number resulted in a nonlinear performance regression which would imply listification. Do you know? – Eric Strom Jun 28 '10 at 21:30
Since the June release of Rakudo converting to a list is lazy, and thus really the same as iterating. – moritz Jun 29 '10 at 9:46

It certainly isn't because everything is an object, because that's true in a number of other languages too (like Ruby). There's no reason why Perl 6 would have to be magnitudes slower than other languages like Perl 5 or Ruby, but the fact is that Rakudo is not as mature as perl or CRuby. There hasn't been much speed optimization yet.

share|improve this answer
Yep, that's exactly why I added in the Ruby example, because comparing perl5 to perl6 performance just didn't seem fair at all :). Do you know if these issues are on the Parrot side or the Rakudo side? – Eric Strom Jun 28 '10 at 20:41

I submitted these to Fefe's language competition in December 2008. is a literal translation of the Perl 5 example, is far more sixier. I have two programs because the two implement a different subset of the spec. Build information is outdated meanwhile. The sources:

#!/usr/bin/env pugs
# Pugs: <> <>
# prerequisite: ghc-6.8.x, not 6.10.x
# svn co
# perl Makefile.PL
# make
# if build stops because of haskeline, do:
#   $HOME/.cabal/bin/cabal update ; $HOME/.cabal/bin/cabal install haskeline

# learn more: <>

my %words;

for =<> {
    for .split {

for (sort { %words{$^b} <=> %words{$^a} }, %words.keys) {
    say "$_ %words{$_}"

#!/usr/bin/env perl6
# Rakudo: <> <>
# svn co parrot
# perl
# make perl6

# Solution contributed by Frank W. & Moritz Lenz
# <>
# learn more: <>

my %words;

$*IN.lines.split(/\s+/).map: { %words{$_}++ };

for %words.pairs.sort: { $^b.value <=> $^a.value } -> $pair {
    say $pair

These were the results in 2008:

$ time ./ < /usr/src/linux/COPYING > foo

real    0m2.529s
user    0m2.464s
sys     0m0.064s

$ time ./ < /usr/src/linux/COPYING > foo

real    0m32.544s
user    0m1.920s
sys     0m0.248s


$ time ./ < /usr/src/linux/COPYING > foo

real    0m5.105s
user    0m4.898s
sys     0m0.096s

$ time ./ < /usr/src/linux/COPYING > foo
Divide by zero
current instr.: '' pc -1 ((unknown file):-1)
Segmentation fault

real    0m3.236s
user    0m0.447s
sys     0m0.080s

Late additions: The crash has been dealt with at The Rakudo program is inefficient, see comments below and

share|improve this answer
As I write this, it's been 6 hours since you said "Pugs result coming when it's finished compiling". Is Pugs really still compiling? :) – Gabe Jun 29 '10 at 4:28
No, I went to sleep. – daxim Jun 29 '10 at 6:53
What's going on with the segfault in the last test, are those times complete? – Eric Strom Jun 29 '10 at 15:14
I suspect "$*IN.lines.split(/\s+/).map: { %words{$_}++ };" should be replaced with "%words{$_}++ for $*IN.lines.split(/\s+/);" since map in sink (void) context is currently broken – Pat Jun 29 '10 at 16:24
Replacing this with $*IN.slurp.words instead -- .slurp reads the entire file into a single string, and .words extracts all the words from a string, basically the opposite way of stating split on whitespace -- shaved 80% off the scripts execution time for my 100-line test file. – Sol Jun 29 '10 at 21:36

Considering that now your test case is optimized to an O(1) algorithm that returns nearly instantly, and that it seems almost like there are several optimizations a week;
I expect quite an performance improvement all around.

$ perl6 -e 'say [+] 1..10**1000; say now - INIT now'
5000000000000000000000000000000000000000000000 ...

Even if that wasn't special-cased for ranges it is still quite a bit faster than it was.
It now does your test calculation in less than a fifth of a second.

$ perl6 -e 'say [+] (1..100000).list; say now - INIT now'
share|improve this answer
Nice! Thanks for using now and INIT. I'm going to have to look them up "now". – Christopher Bottoms Dec 5 '15 at 1:40

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