Benchmark - benchmark running times of Perl code
timethis ($count, "code");
# Use Perl code in strings...
'Name1' => '...code1...',
'Name2' => '...code2...',
# ... or use subroutine references.
'Name1' => sub { ...code1... },
'Name2' => sub { ...code2... },
# cmpthese can be used both ways as well
'Name1' => '...code1...',
'Name2' => '...code2...',
'Name1' => sub { ...code1... },
'Name2' => sub { ...code2... },
$results = timethese($count,
'Name1' => sub { ...code1... },
'Name2' => sub { ...code2... },
$t = timeit($count, '...other code...')
print "$count loops of other code took:",timestr($t),"\n";
$t = countit($time, '...other code...')
print "$count loops of other code took:",timestr($t),"\n";
# enable hires wallclock timing if possible
use Benchmark ':hireswallclock';
The Benchmark module encapsulates a number of routines to help you
figure out how long it takes to execute some code.
timethis - run a chunk of code several times
timethese - run several chunks of code several times
cmpthese - print results of timethese as a comparison chart
timeit - run a chunk of code and see how long it goes
countit - see how many times a chunk of code runs in a given time
Returns the current time. Example:
$td = timediff($t1, $t0);
print "the code took:",timestr($td),"\n";
Enables or disable debugging by setting the C<$Benchmark::Debug> flag:
$t = timeit(10, ' 5 ** $Global ');
Returns the number of iterations.
The following routines will be exported into your namespace
if you use the Benchmark module:
=item timeit(COUNT, CODE)
Arguments: COUNT is the number of times to run the loop, and CODE is
the code to run. CODE may be either a code reference or a string to
be eval'd; either way it will be run in the caller's package.
Returns: a Benchmark object.
=item timethis ( COUNT, CODE, [ TITLE, [ STYLE ]] )
Time COUNT iterations of CODE. CODE may be a string to eval or a
code reference; either way the CODE will run in the caller's package.
Results will be printed to STDOUT as TITLE followed by the times.
TITLE defaults to "timethis COUNT" if none is provided. STYLE
determines the format of the output, as described for timestr() below.
The COUNT can be zero or negative: this means the I<minimum number of
CPU seconds> to run. A zero signifies the default of 3 seconds. For
example to run at least for 10 seconds:
or to run two pieces of code tests for at least 3 seconds:
timethese(0, { test1 => '...', test2 => '...'})
CPU seconds is, in UNIX terms, the user time plus the system time of
the process itself, as opposed to the real (wallclock) time and the
time spent by the child processes. Less than 0.1 seconds is not
accepted (-0.01 as the count, for example, will cause a fatal runtime
Note that the CPU seconds is the B<minimum> time: CPU scheduling and
other operating system factors may complicate the attempt so that a
little bit more time is spent. The benchmark output will, however,
also tell the number of C<$code> runs/second, which should be a more
interesting number than the actually spent seconds.
Returns a Benchmark object.
=item timethese ( COUNT, CODEHASHREF, [ STYLE ] )
The CODEHASHREF is a reference to a hash containing names as keys
and either a string to eval or a code reference for each value.
For each (KEY, VALUE) pair in the CODEHASHREF, this routine will
timethis(COUNT, VALUE, KEY, STYLE)
The routines are called in string comparison order of KEY.
The COUNT can be zero or negative, see timethis().
Returns a hash of Benchmark objects, keyed by name.
=item timediff ( T1, T2 )
Returns the difference between two Benchmark times as a Benchmark
object suitable for passing to timestr().
=item timestr ( TIMEDIFF, [ STYLE, [ FORMAT ] ] )
Returns a string that formats the times in the TIMEDIFF object in
the requested STYLE. TIMEDIFF is expected to be a Benchmark object
similar to that returned by timediff().
STYLE can be any of 'all', 'none', 'noc', 'nop' or 'auto'. 'all' shows
each of the 5 times available ('wallclock' time, user time, system time,
user time of children, and system time of children). 'noc' shows all
except the two children times. 'nop' shows only wallclock and the
two children times. 'auto' (the default) will act as 'all' unless
the children times are both zero, in which case it acts as 'noc'.
FORMAT is the L<printf(3)>-style format specifier (without the
leading '%') to use to print the times. It defaults to '5.2f'.
The following routines will be exported into your namespace
if you specifically ask that they be imported:
=item clearcache ( COUNT )
Clear the cached time for COUNT rounds of the null loop.
=item cmpthese ( COUNT, CODEHASHREF, [ STYLE ] )
=item cmpthese ( RESULTSHASHREF, [ STYLE ] )
Optionally calls timethese(), then outputs comparison chart. This:
cmpthese( -1, { a => "++\$i", b => "\$i *= 2" } ) ;
This chart is sorted from slowest to fastest, and shows the percent speed
difference between each pair of tests.
c<cmpthese> can also be passed the data structure that timethese() returns:
$results = timethese( -1, { a => "++\$i", b => "\$i *= 2" } ) ;
in case you want to see both sets of results.
Returns a reference to an ARRAY of rows, each row is an ARRAY of cells from the
above chart, including labels. This:
my $rows = cmpthese( -1, { a => '++$i', b => '$i *= 2' }, "none" );
returns a data structure like:
[ '', 'Rate', 'b', 'a' ],
[ 'b', '2885232/s', '--', '-59%' ],
[ 'a', '7099126/s', '146%', '--' ],
B<NOTE>: This result value differs from previous versions, which returned
the C<timethese()> result structure. If you want that, just use the two
statement C<timethese>...C<cmpthese> idiom shown above.
Incidently, note the variance in the result values between the two examples;
this is typical of benchmarking. If this were a real benchmark, you would
probably want to run a lot more iterations.
=item countit(TIME, CODE)
Arguments: TIME is the minimum length of time to run CODE for, and CODE is
the code to run. CODE may be either a code reference or a string to
be eval'd; either way it will be run in the caller's package.
TIME is I<not> negative. countit() will run the loop many times to
calculate the speed of CODE before running it for TIME. The actual
time run for will usually be greater than TIME due to system clock
resolution, so it's best to look at the number of iterations divided
by the times that you are concerned with, not just the iterations.
Returns: a Benchmark object.
Disable caching of timings for the null loop. This will force Benchmark
to recalculate these timings for each new piece of code timed.
Enable caching of timings for the null loop. The time taken for COUNT
rounds of the null loop will be calculated only once for each
Returns the sum of two Benchmark times as a Benchmark object suitable
for passing to timestr().
If the Time::HiRes module has been installed, you can specify the
special tag C<:hireswallclock> for Benchmark (if Time::HiRes is not
available, the tag will be silently ignored). This tag will cause the
wallclock time to be measured in microseconds, instead of integer
seconds. Note though that the speed computations are still conducted
in CPU time, not wallclock time.
The data is stored as a list of values from the time and times
($real, $user, $system, $children_user, $children_system, $iters)
in seconds for the whole loop (not divided by the number of rounds).
The timing is done using time(3) and times(3).
Code is executed in the caller's package.
The time of the null loop (a loop with the same
number of rounds but empty loop body) is subtracted
from the time of the real loop.
The null loop times can be cached, the key being the
number of rounds. The caching can be controlled using
Caching is off by default, as it can (usually slightly) decrease
accuracy and does not usually noticably affect runtimes.
use Benchmark qw( cmpthese ) ;
outputs something like this:
Benchmark: running a, b, each for at least 5 CPU seconds...
use Benchmark qw( timethese cmpthese ) ;
outputs something like this:
Benchmark: running a, b, each for at least 5 CPU seconds...
a: 10 wallclock secs ( 5.14 usr + 0.13 sys = 5.27 CPU) @ 3835055.60/s (n=20210743)
b: 5 wallclock secs ( 5.41 usr + 0.00 sys = 5.41 CPU) @ 1574944.92/s (n=8520452)
Benchmark inherits from no other class, except of course
Comparing eval'd strings with code references will give you
inaccurate results: a code reference will show a slightly slower
execution time than the equivalent eval'd string.
The real time timing is done using time(2) and
the granularity is therefore only one second.
Short tests may produce negative figures because perl
can appear to take longer to execute the empty loop
The system time of the null loop might be slightly
more than the system time of the loop with the actual
code and therefore the difference might end up being E<lt> 0.
L<Devel::DProf> - a Perl code profiler
Jarkko Hietaniemi <F<jhi@iki.fi>>, Tim Bunce <F<Tim.Bunce@ig.co.uk>>
=head1 MODIFICATION HISTORY
September 8th, 1994; by Tim Bunce.
March 28th, 1997; by Hugo van der Sanden: added support for code
references and the already documented 'debug' method; revamped
April 04-07th, 1997: by Jarkko Hietaniemi, added the run-for-some-time
September, 1999; by Barrie Slaymaker: math fixes and accuracy and
efficiency tweaks. Added cmpthese(). A result is now returned from
timethese(). Exposed countit() (was runfor()).
December, 2001; by Nicholas Clark: make timestr() recognise the style 'none'
and return an empty string. If cmpthese is calling timethese, make it pass the
style in. (so that 'none' will suppress output). Make sub new dump its
debugging output to STDERR, to be consistent with everything else.
All bugs found while writing a regression test.
September, 2002; by Jarkko Hietaniemi: add ':hireswallclock' special tag.
February, 2004; by Chia-liang Kao: make cmpthese and timestr use time
statistics for children instead of parent when the style is 'nop'.
# evaluate something in a clean lexical environment
sub _doeval
{ no strict
; eval shift }
# put any lexicals at file scope AFTER here
our(@ISA, @EXPORT, @EXPORT_OK, %EXPORT_TAGS, $VERSION);
@EXPORT=qw(timeit timethis timethese timediff timestr);
@EXPORT_OK=qw(timesum cmpthese countit
clearcache clearallcache disablecache enablecache);
%EXPORT_TAGS=( all
=> [ @EXPORT, @EXPORT_OK ] ) ;
# --- ':hireswallclock' special handling
if (eval 'require Time::HiRes') {
import Time
::HiRes
qw(time);
$hirestime = \
&Time
::HiRes
::time;
if (grep { $_ eq ":hireswallclock" } @_) {
@_ = grep { $_ ne ":hireswallclock" } @_;
*mytime
= $hirestime if defined $hirestime;
Benchmark
->export_to_level(1, $class, @_);
our($Debug, $Min_Count, $Min_CPU, $Default_Format, $Default_Style,
%_Usage, %Cache, $Do_Cache);
$Default_Format = '5.2f';
# The cache can cause a slight loss of sys time accuracy. If a
# user does many tests (>10) with *very* large counts (>10000)
# or works on a very slow machine the cache may be useful.
sub debug
{ $Debug = ($_[1] != 0); }
my $calling_sub = (caller(1))[3];
$calling_sub =~ s/^Benchmark:://;
return $_Usage{$calling_sub} || '';
# The cache needs two branches: 's' for strings and 'c' for code. The
# empty loop is different in these two cases.
$_Usage{clearcache
} = <<'USAGE';
usage: clearcache($count);
die usage
unless @_ == 1;
delete $Cache{"$_[0]c"}; delete $Cache{"$_[0]s"};
$_Usage{clearallcache
} = <<'USAGE';
$_Usage{enablecache
} = <<'USAGE';
$_Usage{disablecache
} = <<'USAGE';
# --- Functions to process the 'time' data type
sub new
{ my @t = (mytime
, times, @_ == 2 ?
$_[1] : 0);
print STDERR
"new=@t\n" if $Debug;
sub cpu_p
{ my($r,$pu,$ps,$cu,$cs) = @
{$_[0]}; $pu+$ps ; }
sub cpu_c
{ my($r,$pu,$ps,$cu,$cs) = @
{$_[0]}; $cu+$cs ; }
sub cpu_a
{ my($r,$pu,$ps,$cu,$cs) = @
{$_[0]}; $pu+$ps+$cu+$cs ; }
sub real
{ my($r,$pu,$ps,$cu,$cs) = @
{$_[0]}; $r ; }
sub iters
{ $_[0]->[5] ; }
$_Usage{timediff
} = <<'USAGE';
usage: $result_diff = timediff($result1, $result2);
die usage
unless ref $a and ref $b;
for (my $i=0; $i < @
$a; ++$i) {
push(@r, $a->[$i] - $b->[$i]);
$_Usage{timesum
} = <<'USAGE';
usage: $sum = timesum($result1, $result2);
die usage
unless ref $a and ref $b;
for (my $i=0; $i < @
$a; ++$i) {
push(@r, $a->[$i] + $b->[$i]);
$_Usage{timestr
} = <<'USAGE';
usage: $formatted_result = timestr($result1);
my($tr, $style, $f) = @_;
die usage
unless ref $tr;
warn "bad time value (@t)" unless @t==6;
my($r, $pu, $ps, $cu, $cs, $n) = @t;
my($pt, $ct, $tt) = ($tr->cpu_p, $tr->cpu_c, $tr->cpu_a);
$f = $Default_Format unless defined $f;
# format a time in the required style, other formats may be added here
$style ||= $Default_Style;
return '' if $style eq 'none';
$style = ($ct>0) ?
'all' : 'noc' if $style eq 'auto';
my $s = "@t $style"; # default for unknown style
my $w = $hirestime ?
"%2g" : "%2d";
$s=sprintf("$w wallclock secs (%$f usr %$f sys + %$f cusr %$f csys = %$f CPU)",
$r,$pu,$ps,$cu,$cs,$tt) if $style eq 'all';
$s=sprintf("$w wallclock secs (%$f usr + %$f sys = %$f CPU)",
$r,$pu,$ps,$pt) if $style eq 'noc';
$s=sprintf("$w wallclock secs (%$f cusr + %$f csys = %$f CPU)",
$r,$cu,$cs,$ct) if $style eq 'nop';
$s .= sprintf(" @ %$f/s (n=$n)", $n / ( $style eq 'nop' ?
$cu + $cs : $pu + $ps ))
if $n && ($style eq 'nop' ?
$cu+$cs : $pu+$ps);
print STDERR
"$msg",timestr
($t),"\n" if $Debug;
# --- Functions implementing low-level support for timing loops
$_Usage{runloop
} = <<'USAGE';
usage: runloop($number, [$string | $coderef])
$n+=0; # force numeric now, so garbage won't creep into the eval
croak
"negative loopcount $n" if $n<0;
confess usage
unless defined $c;
my($t0, $t1, $td); # before, after, difference
# find package of caller so we can execute code there
my($curpack) = caller(0);
while (($pack) = caller(++$i)) {
last if $pack ne $curpack;
$subcode = "sub { for (1 .. $n) { local \$_; package $pack; &\$c; } }";
$subcode = "sub { for (1 .. $n) { local \$_; package $pack; $c;} }";
$subref = _doeval
($subcode);
croak
"runloop unable to compile '$c': $@\ncode: $subcode\n" if $@
;
print STDERR
"runloop $n '$subcode'\n" if $Debug;
# Wait for the user timer to tick. This makes the error range more like
# -0.01, +0. If we don't wait, then it's more like -0.01, +0.01. This
# may not seem important, but it significantly reduces the chances of
# getting a too low initial $n in the initial, 'find the minimum' loop
# in &countit. This, in turn, can reduce the number of calls to
# &runloop a lot, and thus reduce additive errors.
my $tbase = Benchmark
->new(0)->[1];
while ( ( $t0 = Benchmark
->new(0) )->[1] == $tbase ) {} ;
$t1 = Benchmark
->new($n);
$td = &timediff
($t1, $t0);
timedebug
("runloop:",$td);
$_Usage{timeit
} = <<'USAGE';
usage: $result = timeit($count, 'code' ); or
$result = timeit($count, sub { code } );
die usage
unless defined $code and
(!ref $code or ref $code eq 'CODE');
printf STDERR
"timeit $n $code\n" if $Debug;
my $cache_key = $n . ( ref( $code ) ?
'c' : 's' );
if ($Do_Cache && exists $Cache{$cache_key} ) {
$wn = $Cache{$cache_key};
$wn = &runloop
($n, ref( $code ) ?
sub { } : '' );
# Can't let our baseline have any iterations, or they get subtracted
$Cache{$cache_key} = $wn;
$wc = &runloop
($n, $code);
$wd = timediff
($wc, $wn);
timedebug
("timeit: ",$wc);
$_Usage{countit
} = <<'USAGE';
usage: $result = countit($time, 'code' ); or
$result = countit($time, sub { code } );
my ( $tmax, $code ) = @_;
if ( not defined $tmax or $tmax == 0 ) {
die "countit($tmax, ...): timelimit cannot be less than $min_for.\n"
# First find the minimum $n that gives a significant timing.
for ($n = 1; ; $n *= 2 ) {
my $td = timeit
($n, $code);
$tc = $td->[1] + $td->[2];
# Get $n high enough that we can guess the final $n with some accuracy.
my $tpra = 0.1 * $tmax; # Target/time practice.
# The 5% fudge is to keep us from iterating again all
# that often (this speeds overall responsiveness when $tmax is big
# and we guess a little low). This does not noticably affect
# accuracy since we're not couting these times.
$n = int( $tpra * 1.05 * $n / $tc ); # Linear approximation.
my $td = timeit
($n, $code);
my $new_tc = $td->[1] + $td->[2];
# Make sure we are making progress.
$tc = $new_tc > 1.2 * $tc ?
$new_tc : 1.2 * $tc;
# Now, do the 'for real' timing(s), repeating until we exceed
# The 5% fudge is because $n is often a few % low even for routines
# with stable times and avoiding extra timeit()s is nice for
$n = int( $n * ( 1.05 * $tmax / $tc ) );
my $td = timeit
($n, $code);
$ttot = 0.01 if $ttot < 0.01;
my $r = $tmax / $ttot - 1; # Linear approximation.
$n = $nmin if $n < $nmin;
return bless [ $rtot, $utot, $stot, $cutot, $cstot, $ntot ];
# --- Functions implementing high-level time-then-print utilities
return $n == 0 ?
$default_for : $n < 0 ?
-$n : undef;
$_Usage{timethis
} = <<'USAGE';
usage: $result = timethis($time, 'code' ); or
$result = timethis($time, sub { code } );
my($n, $code, $title, $style) = @_;
die usage
unless defined $code and
(!ref $code or ref $code eq 'CODE');
croak
"non-integer loopcount $n, stopped" if int($n)<$n;
$title = "timethis $n" unless defined $title;
my $fort = n_to_for
( $n );
$t = countit
( $fort, $code );
$title = "timethis for $fort" unless defined $title;
$style = "" unless defined $style;
printf("%10s: ", $title) unless $style eq 'none';
print timestr
($t, $style, $Default_Format),"\n" unless $style eq 'none';
$n = $forn if defined $forn;
# A conservative warning to spot very silly tests.
# Don't assume that your benchmark is ok simply because
# you don't get this warning!
print " (warning: too few iterations for a reliable count)\n"
|| ($t->real < 1 && $n < 1000)
$_Usage{timethese
} = <<'USAGE';
usage: timethese($count, { Name1 => 'code1', ... }); or
timethese($count, { Name1 => sub { code1 }, ... });
my($n, $alt, $style) = @_;
die usage
unless ref $alt eq 'HASH';
my @names = sort keys %$alt;
$style = "" unless defined $style;
print "Benchmark: " unless $style eq 'none';
croak
"non-integer loopcount $n, stopped" if int($n)<$n;
print "timing $n iterations of" unless $style eq 'none';
print "running" unless $style eq 'none';
print " ", join(', ',@names) unless $style eq 'none';
my $for = n_to_for
( $n );
print ", each" if $n > 1 && $style ne 'none';
print " for at least $for CPU seconds" unless $style eq 'none';
print "...\n" unless $style eq 'none';
# we could save the results in an array and produce a summary here
# sum, min, max, avg etc etc
foreach my $name (@names) {
$results{$name} = timethis
($n, $alt -> {$name}, $name, $style);
$_Usage{cmpthese
} = <<'USAGE';
usage: cmpthese($count, { Name1 => 'code1', ... }); or
cmpthese($count, { Name1 => sub { code1 }, ... }); or
cmpthese($result, $style);
my($count, $code) = @_[0,1];
$style = $_[2] if defined $_[2];
die usage
unless ref $code eq 'HASH';
$results = timethese
($count, $code, ($style || "none"));
$style = "" unless defined $style;
# Flatten in to an array of arrays with the name as the first field
my @vals = map{ [ $_, @
{$results->{$_}} ] } keys %$results;
# The epsilon fudge here is to prevent div by 0. Since clock
# resolutions are much larger, it's below the noise floor.
my $rate = $_->[6] / (( $style eq 'nop' ?
$_->[4] + $_->[5]
: $_->[2] + $_->[3]) + 0.000000000000001 );
@vals = sort { $a->[7] <=> $b->[7] } @vals;
# If more than half of the rates are greater than one...
my $display_as_rate = @vals ?
($vals[$#vals>>1]->[7] > 1) : 0;
$display_as_rate ?
'Rate' : 's/iter',
@col_widths = map { length( $_ ) } @top_row;
# We leave the last column in even though it never has any data. Perhaps
# it should go away. Also, perhaps a style for a single column of
# percentages might be nice.
for my $row_val ( @vals ) {
push @row, $row_val->[0];
$col_widths[0] = length( $row_val->[0] )
if length( $row_val->[0] ) > $col_widths[0];
my $row_rate = $row_val->[7];
# We assume that we'll never get a 0 rate.
my $rate = $display_as_rate ?
$row_rate : 1 / $row_rate;
# Only give a few decimal places before switching to sci. notation,
# since the results aren't usually that accurate anyway.
my $formatted_rate = sprintf( $format, $rate );
push @row, $formatted_rate;
$col_widths[1] = length( $formatted_rate )
if length( $formatted_rate ) > $col_widths[1];
# Columns 2..N = performance ratios
for ( my $col_num = 0 ; $col_num < @vals ; ++$col_num ) {
my $col_val = $vals[$col_num];
elsif ( $col_val->[0] eq $row_val->[0] ) {
my $col_rate = $col_val->[7];
$out = sprintf( "%.0f%%", 100*$row_rate/$col_rate - 100 );
$col_widths[$col_num+2] = length( $out )
if length( $out ) > $col_widths[$col_num+2];
# A little wierdness to set the first column width properly
$col_widths[$col_num+2] = length( $col_val->[0] )
if length( $col_val->[0] ) > $col_widths[$col_num+2];
return \
@rows if $style eq "none";
# Equalize column widths in the chart as much as possible without
# exceeding 80 characters. This does not use or affect cols 0 or 1.
sort { $$a <=> $$b } map { \
$_ } @col_widths[2..$#col_widths];
my $max_width = ${$sorted_width_refs[-1]};
my $total = @col_widths - 1 ;
for ( @col_widths ) { $total += $_ }
my $min_width = ${$sorted_width_refs[0]};
if $min_width == $max_width;
for ( @sorted_width_refs ) {
my $format = join( ' ', map { "%${_}s" } @col_widths ) . "\n";
substr( $format, 1, 0 ) = '-';