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
the requested STYLE. TIMEDIFF is expected to be a Benchmark object
similar to that returned by timediff().
-STYLE can be any of 'all', 'noc', 'nop' or 'auto'. 'all' shows each
-of the 5 times available ('wallclock' time, user time, system time,
+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'.
+'none' prevents output.
FORMAT is the L<printf(3)>-style format specifier (without the
leading '%') to use to print the times. It defaults to '5.2f'.
Clear all cached times.
+=item cmpthese ( COUT, CODEHASHREF, [ STYLE ] )
+
+=item cmpthese ( RESULTSHASHREF )
+
+Optionally calls timethese(), then outputs comparison chart. This
+chart is sorted from slowest to highest, and shows the percent
+speed difference between each pair of tests. Can also be passed
+the data structure that timethese() returns:
+
+ $results = timethese( .... );
+ cmpthese( $results );
+
+Returns the data structure returned by timethese().
+
=item disablecache ( )
Disable caching of timings for the null loop. This will force Benchmark
number of rounds but empty loop body) is subtracted
from the time of the real loop.
-The null loop times are cached, the key being the
+The null loop times can be cached, the key being the
number of rounds. The caching can be controlled using
calls like these:
disablecache();
enablecache();
+Caching is off by default, as it can (usually slightly) decrease
+accuracy and does not usually noticably affect runtimes.
+
=head1 INHERITANCE
Benchmark inherits from no other class, except of course
April 04-07th, 1997: by Jarkko Hietaniemi, added the run-for-some-time
functionality.
+September, 1999; by Barrie Slaymaker: math fixes and accuracy and
+efficiency tweaks. Added cmpthese(). A result is now returned from
+timethese().
+
=cut
# evaluate something in a clean lexical environment
use Exporter;
@ISA=(Exporter);
@EXPORT=qw(timeit timethis timethese timediff timesum timestr);
-@EXPORT_OK=qw(clearcache clearallcache disablecache enablecache);
+@EXPORT_OK=qw(clearcache clearallcache cmpthese disablecache enablecache);
&init;
croak "runloop unable to compile '$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 too low initial $n in the initial, 'find
- # the minimum' loop in &runfor. This, in turn, can reduce the number of calls to
+ # 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 &runfor. This, in turn, can reduce the number of calls to
# &runloop a lot, and thus reduce additive errors.
my $tbase = Benchmark->new(0)->[1];
do {
$t0 = Benchmark->new(0);
- } while ( $t0->[1] == $tbase ) ;
+ } while ( $t0->[1] == $tbase );
&$subref;
$t1 = Benchmark->new($n);
$td = &timediff($t1, $t0);
my($wn, $wc, $wd);
printf STDERR "timeit $n $code\n" if $debug;
- my $cache_key = $n . ( ref( $code ) ? 'c' : 's' ) ;
+ my $cache_key = $n . ( ref( $code ) ? 'c' : 's' );
if ($cache && exists $cache{$cache_key} ) {
$wn = $cache{$cache_key};
} else {
$wn = &runloop($n, ref( $code ) ? sub { undef } : '' );
+ # Can't let our baseline have any iterations, or they get subtracted
+ # out of the result.
+ $wn->[5] = 0;
$cache{$cache_key} = $wn;
}
$wc = &runloop($n, $code);
$wd = timediff($wc, $wn);
-
timedebug("timeit: ",$wc);
timedebug(" - ",$wn);
timedebug(" = ",$wd);
my $default_for = 3;
my $min_for = 0.1;
+
sub runfor {
my ($code, $tmax) = @_;
die "runfor(..., $tmax): timelimit cannot be less than $min_for.\n"
if $tmax < $min_for;
- my ($n, $td, $tc, $ntot, $rtot, $utot, $stot, $cutot, $cstot );
+ my ($n, $tc);
# First find the minimum $n that gives a significant timing.
-
- my $nmin;
+ for ($n = 1; ; $n *= 2 ) {
+ my $td = timeit($n, $code);
+ $tc = $td->[1] + $td->[2];
+ last if $tc > 0.1;
+ }
- for ($n = 1, $tc = 0; ; $n *= 2 ) {
- $td = timeit($n, $code);
+ my $nmin = $n;
+
+ # Get $n high enough that we can guess the final $n with some accuracy.
+ my $tpra = 0.1 * $tmax; # Target/time practice.
+ while ( $tc < $tpra ) {
+ # 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);
$tc = $td->[1] + $td->[2];
- last if $tc > 0.1 ;
}
- $nmin = $n;
-
- my $ttot = 0;
- my $tpra = 0.05 * $tmax; # Target/time practice.
- # Double $n until we have think we have practiced enough.
- for ( ; $ttot < $tpra; $n *= 2 ) {
- $td = timeit($n, $code);
- $ntot += $n;
- $rtot += $td->[0];
- $utot += $td->[1];
- $stot += $td->[2];
- $ttot = $utot + $stot;
+ # Now, do the 'for real' timing(s), repeating until we exceed
+ # the max.
+ my $ntot = 0;
+ my $rtot = 0;
+ my $utot = 0.0;
+ my $stot = 0.0;
+ my $cutot = 0.0;
+ my $cstot = 0.0;
+ my $ttot = 0.0;
+
+ # 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
+ # accuracy's sake.
+ $n = int( $n * ( 1.05 * $tmax / $tc ) );
+
+ while () {
+ my $td = timeit($n, $code);
+ $ntot += $n;
+ $rtot += $td->[0];
+ $utot += $td->[1];
+ $stot += $td->[2];
$cutot += $td->[3];
$cstot += $td->[4];
- }
-
- my $r;
+ $ttot = $utot + $stot;
+ last if $ttot >= $tmax;
- # Then iterate towards the $tmax.
- while ( $ttot < $tmax ) {
- $r = $tmax / $ttot - 1; # Linear approximation.
+ my $r = $tmax / $ttot - 1; # Linear approximation.
$n = int( $r * $ntot );
$n = $nmin if $n < $nmin;
- $td = timeit($n, $code);
- $ntot += $n;
- $rtot += $td->[0];
- $utot += $td->[1];
- $stot += $td->[2];
- $ttot = $utot + $stot;
- $cutot += $td->[3];
- $cstot += $td->[4];
}
return bless [ $rtot, $utot, $stot, $cutot, $cstot, $ntot ];
}
local $| = 1;
$style = "" unless defined $style;
- printf("%10s: ", $title);
- print timestr($t, $style, $defaultfmt),"\n";
+ printf("%10s: ", $title) unless $style eq 'none';
+ print timestr($t, $style, $defaultfmt),"\n" unless $style eq 'none';
$n = $forn if defined $forn;
unless ref $alt eq HASH;
my @names = sort keys %$alt;
$style = "" unless defined $style;
- print "Benchmark: ";
+ print "Benchmark: " unless $style eq 'none';
if ( $n > 0 ) {
croak "non-integer loopcount $n, stopped" if int($n)<$n;
- print "timing $n iterations of";
+ print "timing $n iterations of" unless $style eq 'none';
} else {
- print "running";
+ print "running" unless $style eq 'none';
}
- print " ", join(', ',@names);
+ print " ", join(', ',@names) unless $style eq 'none';
unless ( $n > 0 ) {
my $for = n_to_for( $n );
- print ", each for at least $for CPU seconds";
+ print ", each for at least $for CPU seconds" unless $style eq 'none';
}
- print "...\n";
+ 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
+ my %results;
foreach my $name (@names) {
- timethis ($n, $alt -> {$name}, $name, $style);
+ $results{$name} = timethis ($n, $alt -> {$name}, $name, $style);
}
+
+ return \%results;
}
+sub cmpthese{
+ my $results = ref $_[0] ? $_[0] : timethese( @_ );
+
+ return $results
+ if defined $_[2] && $_[2] eq 'none';
+
+ # Flatten in to an array of arrays with the name as the first field
+ my @vals = map{ [ $_, @{$results->{$_}} ] } keys %$results;
+
+ for (@vals) {
+ # 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] / ( $_->[2] + $_->[3] + 0.000000000000001 );
+ $_->[7] = $rate;
+ }
+
+ # Sort by rate
+ @vals = sort { $a->[7] <=> $b->[7] } @vals;
+
+ # If more than half of the rates are greater than one...
+ my $display_as_rate = $vals[$#vals>>1]->[7] > 1;
+
+ my @rows;
+ my @col_widths;
+
+ my @top_row = (
+ '',
+ $display_as_rate ? 'Rate' : 's/iter',
+ map { $_->[0] } @vals
+ );
+
+ push @rows, \@top_row;
+ @col_widths = map { length( $_ ) } @top_row;
+
+ # Build the data rows
+ # 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 ) {
+ my @row;
+
+ # Column 0 = test name
+ push @row, $row_val->[0];
+ $col_widths[0] = length( $row_val->[0] )
+ if length( $row_val->[0] ) > $col_widths[0];
+
+ # Column 1 = performance
+ my $row_rate = $row_val->[7];
+
+ # We assume that we'll never get a 0 rate.
+ my $a = $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 $format =
+ $a >= 100 ?
+ "%0.0f" :
+ $a >= 10 ?
+ "%0.1f" :
+ $a >= 1 ?
+ "%0.2f" :
+ $a >= 0.1 ?
+ "%0.3f" :
+ "%0.2e";
+
+ $format .= "/s"
+ if $display_as_rate;
+ # Using $b here due to optimizing bug in _58 through _61
+ my $b = sprintf( $format, $a );
+ push @row, $b;
+ $col_widths[1] = length( $b )
+ if length( $b ) > $col_widths[1];
+
+ # Columns 2..N = performance ratios
+ my $skip_rest = 0;
+ for ( my $col_num = 0 ; $col_num < @vals ; ++$col_num ) {
+ my $col_val = $vals[$col_num];
+ my $out;
+ if ( $skip_rest ) {
+ $out = '';
+ }
+ elsif ( $col_val->[0] eq $row_val->[0] ) {
+ $out = "--";
+ # $skip_rest = 1;
+ }
+ else {
+ my $col_rate = $col_val->[7];
+ $out = sprintf( "%.0f%%", 100*$row_rate/$col_rate - 100 );
+ }
+ push @row, $out;
+ $col_widths[$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];
+ }
+ push @rows, \@row;
+ }
+
+ # Equalize column widths in the chart as much as possible without
+ # exceeding 80 characters. This does not use or affect cols 0 or 1.
+ my @sorted_width_refs =
+ sort { $$a <=> $$b } map { \$_ } @col_widths[2..$#col_widths];
+ my $max_width = ${$sorted_width_refs[-1]};
+
+ my $total = 0;
+ for ( @col_widths ) { $total += $_ }
+
+ STRETCHER:
+ while ( $total < 80 ) {
+ my $min_width = ${$sorted_width_refs[0]};
+ last
+ if $min_width == $max_width;
+ for ( @sorted_width_refs ) {
+ last
+ if $$_ > $min_width;
+ ++$$_;
+ ++$total;
+ last STRETCHER
+ if $total >= 80;
+ }
+ }
+
+ # Dump the output
+ my $format = join( ' ', map { "%${_}s" } @col_widths ) . "\n";
+ substr( $format, 1, 0 ) = '-';
+ for ( @rows ) {
+ printf $format, @$_;
+ }
+
+ return $results;
+}
+
+
1;