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March 10, 2013 09:20
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patched Benchmark.pm: croak if return values are wrong.
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440c440 | |
< clearcache clearallcache disablecache enablecache); | |
--- | |
> clearcache clearallcache disablecache enablecache checkreturn); | |
471c471 | |
< %_Usage, %Cache, $Do_Cache); | |
--- | |
> %_Usage, %Cache, $Do_Cache, $Check_Return, $Return_Value); | |
478a479 | |
> $Check_Return = 0; | |
532a534 | |
> sub checkreturn { $Check_Return = ($_[1] != 0); } | |
643a646 | |
> my $checkref; | |
646a650,652 | |
> if ($Check_Return) { | |
> $checkref = eval "sub { local \$_; package $pack; &\$c; }"; | |
> } | |
650a657,659 | |
> if ($Check_Return) { | |
> $checkref = _doeval("sub { local \$_; package $pack; $c; }"); | |
> } | |
654a664,672 | |
> if ($Check_Return) { | |
> my $retval = $checkref->(); | |
> $Return_Value = $retval unless defined $Return_Value; | |
> if ( defined $Return_Value && defined $retval | |
> && $Return_Value ne $retval ) { | |
> croak "return values are wrong $Return_Value from '$c' : $retval" ; | |
> } | |
> } | |
> |
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package Benchmark; | |
use strict; | |
=head1 NAME | |
Benchmark - benchmark running times of Perl code | |
=head1 SYNOPSIS | |
use Benchmark qw(:all) ; | |
timethis ($count, "code"); | |
# Use Perl code in strings... | |
timethese($count, { | |
'Name1' => '...code1...', | |
'Name2' => '...code2...', | |
}); | |
# ... or use subroutine references. | |
timethese($count, { | |
'Name1' => sub { ...code1... }, | |
'Name2' => sub { ...code2... }, | |
}); | |
# cmpthese can be used both ways as well | |
cmpthese($count, { | |
'Name1' => '...code1...', | |
'Name2' => '...code2...', | |
}); | |
cmpthese($count, { | |
'Name1' => sub { ...code1... }, | |
'Name2' => sub { ...code2... }, | |
}); | |
# ...or in two stages | |
$results = timethese($count, | |
{ | |
'Name1' => sub { ...code1... }, | |
'Name2' => sub { ...code2... }, | |
}, | |
'none' | |
); | |
cmpthese( $results ) ; | |
$t = timeit($count, '...other code...') | |
print "$count loops of other code took:",timestr($t),"\n"; | |
$t = countit($time, '...other code...') | |
$count = $t->iters ; | |
print "$count loops of other code took:",timestr($t),"\n"; | |
# enable hires wallclock timing if possible | |
use Benchmark ':hireswallclock'; | |
=head1 DESCRIPTION | |
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 | |
=head2 Methods | |
=over 10 | |
=item new | |
Returns the current time. Example: | |
use Benchmark; | |
$t0 = Benchmark->new; | |
# ... your code here ... | |
$t1 = Benchmark->new; | |
$td = timediff($t1, $t0); | |
print "the code took:",timestr($td),"\n"; | |
=item debug | |
Enables or disable debugging by setting the C<$Benchmark::Debug> flag: | |
Benchmark->debug(1); | |
$t = timeit(10, ' 5 ** $Global '); | |
Benchmark->debug(0); | |
=item iters | |
Returns the number of iterations. | |
=back | |
=head2 Standard Exports | |
The following routines will be exported into your namespace | |
if you use the Benchmark module: | |
=over 10 | |
=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: | |
timethis(-10, $code) | |
or to run two pieces of code tests for at least 3 seconds: | |
timethese(0, { test1 => '...', test2 => '...'}) | |
CPU seconds is, in UNIX terms, the user time plus the system time of | |
the process itself, as opposed to the real (wallclock) time and the | |
time spent by the child processes. Less than 0.1 seconds is not | |
accepted (-0.01 as the count, for example, will cause a fatal runtime | |
exception). | |
Note that the CPU seconds is the B<minimum> time: CPU scheduling and | |
other operating system factors may complicate the attempt so that a | |
little bit more time is spent. The benchmark output will, however, | |
also tell the number of C<$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 | |
call | |
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 reference 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'. | |
'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'. | |
=back | |
=head2 Optional Exports | |
The following routines will be exported into your namespace | |
if you specifically ask that they be imported: | |
=over 10 | |
=item clearcache ( COUNT ) | |
Clear the cached time for COUNT rounds of the null loop. | |
=item clearallcache ( ) | |
Clear all cached times. | |
=item cmpthese ( COUNT, CODEHASHREF, [ STYLE ] ) | |
=item cmpthese ( RESULTSHASHREF, [ STYLE ] ) | |
Optionally calls timethese(), then outputs comparison chart. This: | |
cmpthese( -1, { a => "++\$i", b => "\$i *= 2" } ) ; | |
outputs a chart like: | |
Rate b a | |
b 2831802/s -- -61% | |
a 7208959/s 155% -- | |
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" } ) ; | |
cmpthese( $results ); | |
in case you want to see both sets of results. | |
If the first argument is an unblessed hash reference, | |
that is RESULTSHASHREF; otherwise that is COUNT. | |
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. | |
=item disablecache ( ) | |
Disable caching of timings for the null loop. This will force Benchmark | |
to recalculate these timings for each new piece of code timed. | |
=item enablecache ( ) | |
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 | |
different COUNT used. | |
=item timesum ( T1, T2 ) | |
Returns the sum of two Benchmark times as a Benchmark object suitable | |
for passing to timestr(). | |
=back | |
=head2 :hireswallclock | |
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. | |
=head1 NOTES | |
The data is stored as a list of values from the time and times | |
functions: | |
($real, $user, $system, $children_user, $children_system, $iters) | |
in seconds for the whole loop (not divided by the number of rounds). | |
The timing is done using time(3) and times(3). | |
Code is executed in the caller's package. | |
The time of the null loop (a loop with the same | |
number of rounds but empty loop body) is subtracted | |
from the time of the real loop. | |
The null loop times can be cached, the key being the | |
number of rounds. The caching can be controlled using | |
calls like these: | |
clearcache($key); | |
clearallcache(); | |
disablecache(); | |
enablecache(); | |
Caching is off by default, as it can (usually slightly) decrease | |
accuracy and does not usually noticably affect runtimes. | |
=head1 EXAMPLES | |
For example, | |
use Benchmark qw( cmpthese ) ; | |
$x = 3; | |
cmpthese( -5, { | |
a => sub{$x*$x}, | |
b => sub{$x**2}, | |
} ); | |
outputs something like this: | |
Benchmark: running a, b, each for at least 5 CPU seconds... | |
Rate b a | |
b 1559428/s -- -62% | |
a 4152037/s 166% -- | |
while | |
use Benchmark qw( timethese cmpthese ) ; | |
$x = 3; | |
$r = timethese( -5, { | |
a => sub{$x*$x}, | |
b => sub{$x**2}, | |
} ); | |
cmpthese $r; | |
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) | |
Rate b a | |
b 1574945/s -- -59% | |
a 3835056/s 144% -- | |
=head1 INHERITANCE | |
Benchmark inherits from no other class, except of course | |
for Exporter. | |
=head1 CAVEATS | |
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 | |
than a short test; try: | |
timethis(100,'1'); | |
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. | |
=head1 SEE ALSO | |
L<Devel::DProf> - a Perl code profiler | |
=head1 AUTHORS | |
Jarkko Hietaniemi <F<[email protected]>>, Tim Bunce <F<[email protected]>> | |
=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 | |
documentation. | |
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(). 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'. | |
November, 2007; by Christophe Grosjean: make cmpthese and timestr compute | |
time consistently with style argument, default is 'all' not 'noc' any more. | |
=cut | |
# evaluate something in a clean lexical environment | |
sub _doeval { no strict; eval shift } | |
# | |
# put any lexicals at file scope AFTER here | |
# | |
use Carp; | |
use Exporter; | |
our(@ISA, @EXPORT, @EXPORT_OK, %EXPORT_TAGS, $VERSION); | |
@ISA=qw(Exporter); | |
@EXPORT=qw(timeit timethis timethese timediff timestr); | |
@EXPORT_OK=qw(timesum cmpthese countit | |
clearcache clearallcache disablecache enablecache checkreturn); | |
%EXPORT_TAGS=( all => [ @EXPORT, @EXPORT_OK ] ) ; | |
$VERSION = 1.11; | |
# --- ':hireswallclock' special handling | |
my $hirestime; | |
sub mytime () { time } | |
init(); | |
sub BEGIN { | |
if (eval 'require Time::HiRes') { | |
import Time::HiRes qw(time); | |
$hirestime = \&Time::HiRes::time; | |
} | |
} | |
sub import { | |
my $class = shift; | |
if (grep { $_ eq ":hireswallclock" } @_) { | |
@_ = grep { $_ ne ":hireswallclock" } @_; | |
local $^W=0; | |
*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, $Check_Return, $Return_Value); | |
sub init { | |
$Debug = 0; | |
$Min_Count = 4; | |
$Min_CPU = 0.4; | |
$Default_Format = '5.2f'; | |
$Default_Style = 'auto'; | |
$Check_Return = 0; | |
# 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. | |
disablecache(); | |
clearallcache(); | |
} | |
sub debug { $Debug = ($_[1] != 0); } | |
sub usage { | |
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); | |
USAGE | |
sub clearcache { | |
die usage unless @_ == 1; | |
delete $Cache{"$_[0]c"}; delete $Cache{"$_[0]s"}; | |
} | |
$_Usage{clearallcache} = <<'USAGE'; | |
usage: clearallcache(); | |
USAGE | |
sub clearallcache { | |
die usage if @_; | |
%Cache = (); | |
} | |
$_Usage{enablecache} = <<'USAGE'; | |
usage: enablecache(); | |
USAGE | |
sub enablecache { | |
die usage if @_; | |
$Do_Cache = 1; | |
} | |
$_Usage{disablecache} = <<'USAGE'; | |
usage: disablecache(); | |
USAGE | |
sub disablecache { | |
die usage if @_; | |
$Do_Cache = 0; | |
} | |
sub checkreturn { $Check_Return = ($_[1] != 0); } | |
# --- Functions to process the 'time' data type | |
sub new { my @t = (mytime, times, @_ == 2 ? $_[1] : 0); | |
print STDERR "new=@t\n" if $Debug; | |
bless \@t; } | |
sub cpu_p { my($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, $result2); | |
USAGE | |
sub timediff { | |
my($a, $b) = @_; | |
die usage unless ref $a and ref $b; | |
my @r; | |
for (my $i=0; $i < @$a; ++$i) { | |
push(@r, $a->[$i] - $b->[$i]); | |
} | |
#die "Bad timediff(): ($r[1] + $r[2]) <= 0 (@$a[1,2]|@$b[1,2])\n" | |
# if ($r[1] + $r[2]) < 0; | |
bless \@r; | |
} | |
$_Usage{timesum} = <<'USAGE'; | |
usage: $sum = timesum($result1, $result2); | |
USAGE | |
sub timesum { | |
my($a, $b) = @_; | |
die usage unless ref $a and ref $b; | |
my @r; | |
for (my $i=0; $i < @$a; ++$i) { | |
push(@r, $a->[$i] + $b->[$i]); | |
} | |
bless \@r; | |
} | |
$_Usage{timestr} = <<'USAGE'; | |
usage: $formatted_result = timestr($result1); | |
USAGE | |
sub timestr { | |
my($tr, $style, $f) = @_; | |
die usage unless ref $tr; | |
my @t = @$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'; | |
my $elapsed = do { | |
if ($style eq 'nop') {$cu+$cs} | |
elsif ($style eq 'noc') {$pu+$ps} | |
else {$cu+$cs+$pu+$ps} | |
}; | |
$s .= sprintf(" @ %$f/s (n=$n)",$n/($elapsed)) if $n && $elapsed; | |
$s; | |
} | |
sub timedebug { | |
my($msg, $t) = @_; | |
print STDERR "$msg",timestr($t),"\n" if $Debug; | |
} | |
# --- Functions implementing low-level support for timing loops | |
$_Usage{runloop} = <<'USAGE'; | |
usage: runloop($number, [$string | $coderef]) | |
USAGE | |
sub runloop { | |
my($n, $c) = @_; | |
$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); | |
my($i, $pack)= 0; | |
while (($pack) = caller(++$i)) { | |
last if $pack ne $curpack; | |
} | |
my ($subcode, $subref); | |
my $checkref; | |
if (ref $c eq 'CODE') { | |
$subcode = "sub { for (1 .. $n) { local \$_; package $pack; &\$c; } }"; | |
$subref = eval $subcode; | |
if ($Check_Return) { | |
$checkref = eval "sub { local \$_; package $pack; &\$c; }"; | |
} | |
} | |
else { | |
$subcode = "sub { for (1 .. $n) { local \$_; package $pack; $c;} }"; | |
$subref = _doeval($subcode); | |
if ($Check_Return) { | |
$checkref = _doeval("sub { local \$_; package $pack; $c; }"); | |
} | |
} | |
croak "runloop unable to compile '$c': $@\ncode: $subcode\n" if $@; | |
print STDERR "runloop $n '$subcode'\n" if $Debug; | |
if ($Check_Return) { | |
my $retval = $checkref->(); | |
$Return_Value = $retval unless defined $Return_Value; | |
if ( defined $Return_Value && defined $retval | |
&& $Return_Value ne $retval ) { | |
croak "return values are wrong $Return_Value from '$c' : $retval" ; | |
} | |
} | |
# 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 ) {} ; | |
$subref->(); | |
$t1 = Benchmark->new($n); | |
$td = &timediff($t1, $t0); | |
timedebug("runloop:",$td); | |
$td; | |
} | |
$_Usage{timeit} = <<'USAGE'; | |
usage: $result = timeit($count, 'code' ); or | |
$result = timeit($count, sub { code } ); | |
USAGE | |
sub timeit { | |
my($n, $code) = @_; | |
my($wn, $wc, $wd); | |
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}; | |
} else { | |
$wn = &runloop($n, ref( $code ) ? sub { } : '' ); | |
# 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); | |
$wd; | |
} | |
my $default_for = 3; | |
my $min_for = 0.1; | |
$_Usage{countit} = <<'USAGE'; | |
usage: $result = countit($time, 'code' ); or | |
$result = countit($time, sub { code } ); | |
USAGE | |
sub countit { | |
my ( $tmax, $code ) = @_; | |
die usage unless @_; | |
if ( not defined $tmax or $tmax == 0 ) { | |
$tmax = $default_for; | |
} elsif ( $tmax < 0 ) { | |
$tmax = -$tmax; | |
} | |
die "countit($tmax, ...): timelimit cannot be less than $min_for.\n" | |
if $tmax < $min_for; | |
my ($n, $tc); | |
# First find the minimum $n that gives a significant timing. | |
my $zeros=0; | |
for ($n = 1; ; $n *= 2 ) { | |
my $td = timeit($n, $code); | |
$tc = $td->[1] + $td->[2]; | |
if ( $tc <= 0 and $n > 1024 ) { | |
++$zeros > 16 | |
and die "Timing is consistently zero in estimation loop, cannot benchmark. N=$n\n"; | |
} else { | |
$zeros = 0; | |
} | |
last if $tc > 0.1; | |
} | |
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); | |
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 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 ) ); | |
$zeros=0; | |
while () { | |
my $td = timeit($n, $code); | |
$ntot += $n; | |
$rtot += $td->[0]; | |
$utot += $td->[1]; | |
$stot += $td->[2]; | |
$cutot += $td->[3]; | |
$cstot += $td->[4]; | |
$ttot = $utot + $stot; | |
last if $ttot >= $tmax; | |
if ( $ttot <= 0 ) { | |
++$zeros > 16 | |
and die "Timing is consistently zero, cannot benchmark. N=$n\n"; | |
} else { | |
$zeros = 0; | |
} | |
$ttot = 0.01 if $ttot < 0.01; | |
my $r = $tmax / $ttot - 1; # Linear approximation. | |
$n = int( $r * $ntot ); | |
$n = $nmin if $n < $nmin; | |
} | |
return bless [ $rtot, $utot, $stot, $cutot, $cstot, $ntot ]; | |
} | |
# --- Functions implementing high-level time-then-print utilities | |
sub n_to_for { | |
my $n = shift; | |
return $n == 0 ? $default_for : $n < 0 ? -$n : undef; | |
} | |
$_Usage{timethis} = <<'USAGE'; | |
usage: $result = timethis($time, 'code' ); or | |
$result = timethis($time, sub { code } ); | |
USAGE | |
sub timethis{ | |
my($n, $code, $title, $style) = @_; | |
my($t, $forn); | |
die usage unless defined $code and | |
(!ref $code or ref $code eq 'CODE'); | |
if ( $n > 0 ) { | |
croak "non-integer loopcount $n, stopped" if int($n)<$n; | |
$t = timeit($n, $code); | |
$title = "timethis $n" unless defined $title; | |
} else { | |
my $fort = n_to_for( $n ); | |
$t = countit( $fort, $code ); | |
$title = "timethis for $fort" unless defined $title; | |
$forn = $t->[-1]; | |
} | |
local $| = 1; | |
$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" | |
if $n < $Min_Count | |
|| ($t->real < 1 && $n < 1000) | |
|| $t->cpu_a < $Min_CPU; | |
$t; | |
} | |
$_Usage{timethese} = <<'USAGE'; | |
usage: timethese($count, { Name1 => 'code1', ... }); or | |
timethese($count, { Name1 => sub { code1 }, ... }); | |
USAGE | |
sub timethese{ | |
my($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'; | |
if ( $n > 0 ) { | |
croak "non-integer loopcount $n, stopped" if int($n)<$n; | |
print "timing $n iterations of" unless $style eq 'none'; | |
} else { | |
print "running" unless $style eq 'none'; | |
} | |
print " ", join(', ',@names) unless $style eq 'none'; | |
unless ( $n > 0 ) { | |
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 | |
my %results; | |
foreach my $name (@names) { | |
$results{$name} = timethis ($n, $alt -> {$name}, $name, $style); | |
} | |
return \%results; | |
} | |
$_Usage{cmpthese} = <<'USAGE'; | |
usage: cmpthese($count, { Name1 => 'code1', ... }); or | |
cmpthese($count, { Name1 => sub { code1 }, ... }); or | |
cmpthese($result, $style); | |
USAGE | |
sub cmpthese{ | |
my ($results, $style); | |
# $count can be a blessed object. | |
if ( ref $_[0] eq 'HASH' ) { | |
($results, $style) = @_; | |
} | |
else { | |
my($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; | |
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 $elapsed = do { | |
if ($style eq 'nop') {$_->[4]+$_->[5]} | |
elsif ($style eq 'noc') {$_->[2]+$_->[3]} | |
else {$_->[2]+$_->[3]+$_->[4]+$_->[5]} | |
}; | |
my $rate = $_->[6]/(($elapsed)+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[$#vals>>1]->[7] > 1) : 0; | |
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 $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 $format = | |
$rate >= 100 ? | |
"%0.0f" : | |
$rate >= 10 ? | |
"%0.1f" : | |
$rate >= 1 ? | |
"%0.2f" : | |
$rate >= 0.1 ? | |
"%0.3f" : | |
"%0.2e"; | |
$format .= "/s" | |
if $display_as_rate; | |
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 | |
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; | |
} | |
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. | |
my @sorted_width_refs = | |
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 += $_ } | |
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 \@rows ; | |
} | |
1; |
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