#!/usr/bin/perl -w # Copyright (C) 2004,2005,2006,2006,2008,2009,2010 Ole Tange, # http://ole.tange.dk # # Copyright (C) 2010,2011 Ole Tange, http://ole.tange.dk and Free # Software Foundation, Inc. # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, but # WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program; if not, see # or write to the Free Software Foundation, Inc., 51 Franklin St, # Fifth Floor, Boston, MA 02110-1301 USA use strict; use Getopt::Long; $Global::progname="niceload"; $Global::version = 20130514; Getopt::Long::Configure("bundling","require_order"); get_options_from_array(\@ARGV) || die_usage(); if($opt::version) { version(); exit 0; } if($opt::help) { help(); exit 0; } if($opt::factor and $opt::suspend) { # You cannot have --suspend and --factor help(); exit; } if(not (defined $opt::start_io or defined $opt::run_io or defined $opt::start_load or defined $opt::run_load or defined $opt::start_mem or defined $opt::run_mem or defined $opt::start_noswap or defined $opt::run_noswap or defined $opt::io or defined $opt::load or defined $opt::mem or defined $opt::noswap)) { # Default is --runload=1 $opt::run_load = 1; } if(not defined $opt::start_io) { $opt::start_io = $opt::io; } if(not defined $opt::run_io) { $opt::run_io = $opt::io; } if(not defined $opt::start_load) { $opt::start_load = $opt::load; } if(not defined $opt::run_load) { $opt::run_load = $opt::load; } if(not defined $opt::start_mem) { $opt::start_mem = $opt::mem; } if(not defined $opt::run_mem) { $opt::run_mem = $opt::mem; } if(not defined $opt::start_noswap) { $opt::start_noswap = $opt::noswap; } if(not defined $opt::run_noswap) { $opt::run_noswap = $opt::noswap; } if(defined $opt::load) { multiply_binary_prefix($opt::load); } my $limit = Limit->new(); my $process = Process->new($opt::nice,@ARGV); $::exitstatus = 0; if(@opt::prg) { # Find all pids of prg my $out = `pidof -x @opt::prg`; $process->set_pid(split /\s+/,$out); } elsif(@opt::pid) { $process->set_pid(@opt::pid); } elsif (@ARGV) { # Wait until limit is below start_limit and run_limit while($limit->over_start_limit() or ($limit->hard() and $limit->over_run_limit())) { $limit->sleep_for_recheck(); } $process->start(); } while($process->is_alive()) { if($limit->over_run_limit()) { $process->suspend(); $limit->sleep_for_recheck(); if(not $limit->hard()) { $process->resume(); $limit->sleep_while_running(); } } else { $process->resume(); $limit->sleep_while_running(); } } exit($::exitstatus); sub uniq { # Remove duplicates and return unique values return keys %{{ map { $_ => 1 } @_ }}; } sub multiply_binary_prefix { # Evalualte numbers with binary prefix # k=10^3, m=10^6, g=10^9, t=10^12, p=10^15, e=10^18, z=10^21, y=10^24 # K=2^10, M=2^20, G=2^30, T=2^40, P=2^50, E=2^70, Z=2^80, Y=2^80 # Ki=2^10, Mi=2^20, Gi=2^30, Ti=2^40, Pi=2^50, Ei=2^70, Zi=2^80, Yi=2^80 # ki=2^10, mi=2^20, gi=2^30, ti=2^40, pi=2^50, ei=2^70, zi=2^80, yi=2^80 # 13G = 13*1024*1024*1024 = 13958643712 my $s = shift; $s =~ s/k/*1000/g; $s =~ s/M/*1000*1000/g; $s =~ s/G/*1000*1000*1000/g; $s =~ s/T/*1000*1000*1000*1000/g; $s =~ s/P/*1000*1000*1000*1000*1000/g; $s =~ s/E/*1000*1000*1000*1000*1000*1000/g; $s =~ s/Z/*1000*1000*1000*1000*1000*1000*1000/g; $s =~ s/Y/*1000*1000*1000*1000*1000*1000*1000*1000/g; $s =~ s/X/*1000*1000*1000*1000*1000*1000*1000*1000*1000/g; $s =~ s/Ki?/*1024/gi; $s =~ s/Mi?/*1024*1024/gi; $s =~ s/Gi?/*1024*1024*1024/gi; $s =~ s/Ti?/*1024*1024*1024*1024/gi; $s =~ s/Pi?/*1024*1024*1024*1024*1024/gi; $s =~ s/Ei?/*1024*1024*1024*1024*1024*1024/gi; $s =~ s/Zi?/*1024*1024*1024*1024*1024*1024*1024/gi; $s =~ s/Yi?/*1024*1024*1024*1024*1024*1024*1024*1024/gi; $s =~ s/Xi?/*1024*1024*1024*1024*1024*1024*1024*1024*1024/gi; $s = eval $s; return $s; } sub get_options_from_array { # Run GetOptions on @array # Returns: # true if parsing worked # false if parsing failed # @array is changed my $array_ref = shift; # A bit of shuffling of @ARGV needed as GetOptionsFromArray is not # supported everywhere my @save_argv; my $this_is_ARGV = (\@::ARGV == $array_ref); if(not $this_is_ARGV) { @save_argv = @::ARGV; @::ARGV = @{$array_ref}; } my @retval = GetOptions ("debug|D" => \$opt::debug, "factor|f=s" => \$opt::factor, "hard|H" => \$opt::hard, "soft|S" => \$opt::soft, "sensor=s" => \$opt::sensor, "si|sio|startio|start-io=s" => \$opt::start_io, "ri|rio|runio|run-io=s" => \$opt::run_io, "io|I=s" => \$opt::io, "sl|startload|start-load=s" => \$opt::start_load, "rl|runload|run-load=s" => \$opt::run_load, "load|L|l=s" => \$opt::load, "sm|startmem|start-mem=s" => \$opt::start_mem, "rm|runmem|run-mem=s" => \$opt::run_mem, "mem|M=s" => \$opt::mem, "sn|startnoswap|start-noswap|start-no-swap" => \$opt::start_noswap, "rn|runnoswap|run-noswap|run-no-swap" => \$opt::run_noswap, "noswap|N" => \$opt::noswap, "nice|n=i" => \$opt::nice, "program|prg=s" => \@opt::prg, "process|pid|p=s" => \@opt::pid, "suspend|s=s" => \$opt::suspend, "recheck|t=s" => \$opt::recheck, "quote|q" => \$opt::quote, "help|h" => \$opt::help, "verbose|v" => \$opt::verbose, "version|V" => \$opt::version, ); if(not $this_is_ARGV) { @{$array_ref} = @::ARGV; @::ARGV = @save_argv; } return @retval; } sub die_usage { help(); exit 1; } sub help { print q{ Usage: niceload [-v] [-n niceness] [-L loadavg] [-I io] [-N] [-M mem] [-s suspend_sec|-f factor] [-H] [-S] command or -p pid }; } sub die_bug { my $bugid = shift; print STDERR ("$Global::progname: This should not happen. You have found a bug.\n", "Please contact and include:\n", "* The version number: $Global::version\n", "* The bugid: $bugid\n", "* The command line being run\n", "* The files being read (put the files on a webserver if they are big)\n", "\n", "If you get the error on smaller/fewer files, please include those instead.\n"); exit(255); } sub usleep { # Sleep this many milliseconds. my $secs = shift; ::debug("Sleeping ",$secs," millisecs\n"); select(undef, undef, undef, $secs/1000); } sub debug { if($opt::debug) { print STDERR @_; } } sub my_dump { # Returns: # ascii expression of object if Data::Dump(er) is installed # error code otherwise my @dump_this = (@_); eval "use Data::Dump qw(dump);"; if ($@) { # Data::Dump not installed eval "use Data::Dumper;"; if ($@) { my $err = "Neither Data::Dump nor Data::Dumper is installed\n". "Not dumping output\n"; print STDERR $err; return $err; } else { return Dumper(@dump_this); } } else { eval "use Data::Dump qw(dump);"; return (Data::Dump::dump(@dump_this)); } } sub version { # Returns: N/A print join("\n", "GNU $Global::progname $Global::version", "Copyright (C) 2004,2005,2006,2007,2008,2009 Ole Tange", "Copyright (C) 2010,2011 Ole Tange and Free Software Foundation, Inc.", "License GPLv3+: GNU GPL version 3 or later ", "This is free software: you are free to change and redistribute it.", "GNU $Global::progname comes with no warranty.", "", "Web site: http://www.gnu.org/software/parallel\n" ); } sub max { # Returns: # Maximum value of array my $max; for (@_) { # Skip undefs defined $_ or next; defined $max or do { $max = $_; next; }; # Set $_ to the first non-undef $max = ($max > $_) ? $max : $_; } return $max; } sub min { # Returns: # Minimum value of array my $min; for (@_) { # Skip undefs defined $_ or next; defined $min or do { $min = $_; next; }; # Set $_ to the first non-undef $min = ($min < $_) ? $min : $_; } return $min; } package Process; sub new { my $class = shift; my $nice = shift; my @ARGV = @_; if($nice) { unshift(@ARGV, "nice", "-n", $nice); } return bless { 'running' => 0, # Is the process running now? 'command' => [@ARGV], }, ref($class) || $class; } sub pgrp { my $self = shift; my @pgrp; if(not $self->{'pgrp'}) { for(@{$self->{'pids'}}) { push @pgrp,-getpgrp($_); } @pgrp = ::uniq(@pgrp); @{$self->{'pgrp'}} = @pgrp; } return @{$self->{'pgrp'}}; } sub set_pid { my $self = shift; push(@{$self->{'pids'}},@_); $self->{'running'} = 1; $::exitstatus = 0; } sub start { # Start the program my $self = shift; ::debug("Starting @{$self->{'command'}}\n"); $self->{'running'} = 1; if($self->{'pid'} = fork) { # set signal handler to kill children if parent is killed push @{$self->{'pids'}}, $self->{'pid'}; $Global::process = $self; $SIG{CHLD} = \&REAPER; $SIG{INT}=\&kill_child_INT; $SIG{TSTP}=\&kill_child_TSTP; $SIG{CONT}=\&kill_child_CONT; sleep 1; # Give child time to setpgrp(0,0); } else { setpgrp(0,0); ::debug("Child pid: $$, pgrp: ",getpgrp $$,"\n"); ::debug("@{$self->{'command'}}\n"); if($opt::quote) { system(@{$self->{'command'}}); } else { system("@{$self->{'command'}}"); } $::exitstatus = $? >> 8; $::exitsignal = $? & 127; ::debug("Child exit $::exitstatus\n"); exit($::exitstatus); } } use POSIX ":sys_wait_h"; sub REAPER { my $stiff; while (($stiff = waitpid(-1, &WNOHANG)) > 0) { # do something with $stiff if you want $::exitstatus = $? >> 8; $::exitsignal = $? & 127; } $SIG{CHLD} = \&REAPER; # install *after* calling waitpid } sub kill_child_CONT { my $self = $Global::process; ::debug("SIGCONT received. Killing @{$self->{'pgrp'}}\n"); kill CONT => $self->pgrp(); } sub kill_child_TSTP { my $self = $Global::process; ::debug("SIGTSTP received. Killing $self->{'pid'} and self ($$)\n"); kill TSTP => $self->pgrp(); kill STOP => -$$; kill STOP => $$; } sub kill_child_INT { my $self = $Global::process; ::debug("SIGINT received. Killing $self->{'pid'} Exit\n"); kill INT => $self->pgrp(); exit; } sub resume { my $self = shift; ::debug("Resume @{$self->{'pids'}}\n"); if(not $self->{'running'}) { # - = PID group map { kill "CONT", -$_ } @{$self->{'pids'}}; # If using -p it is not in a group map { kill "CONT", $_ } @{$self->{'pids'}}; $self->{'running'} = 1; } } sub suspend { my $self = shift; ::debug("Suspend @{$self->{'pids'}}\n"); if($self->{'running'}) { # - = PID group map { kill "STOP", -$_ } @{$self->{'pids'}}; # If using -p it is not in a group map { kill "STOP", $_ } @{$self->{'pids'}}; $self->{'running'} = 0; } } sub is_alive { # The process is dead if none of the pids exist my $self = shift; my ($exists) = 0; for my $pid (@{$self->{'pids'}}) { if(kill 0 => $pid) { $exists++ } } ::debug("is_alive: $exists\n"); return $exists; } package Limit; sub new { my $class = shift; my %limits = @_; my $hard = $opt::soft ? 0 : $opt::hard; my $runio = $opt::run_io ? ::multiply_binary_prefix($opt::run_io) : 0; my $startio = $opt::start_io ? ::multiply_binary_prefix($opt::start_io) : 0; my $runload = $opt::run_load ? ::multiply_binary_prefix($opt::run_load) : 0; my $startload = $opt::start_load ? ::multiply_binary_prefix($opt::start_load) : 0; my $runmem = $opt::run_mem ? ::multiply_binary_prefix($opt::run_mem) : 0; my $startmem = $opt::start_mem ? ::multiply_binary_prefix($opt::start_mem) : 0; my $runnoswap = $opt::run_noswap ? ::multiply_binary_prefix($opt::run_noswap) : 0; my $startnoswap = $opt::start_noswap ? ::multiply_binary_prefix($opt::start_noswap) : 0; return bless { 'hard' => $hard, 'recheck' => 1, # Default 'runtime' => 1, # Default 'runio' => $runio, 'startio' => $startio, 'runload' => $runload, 'startload' => $startload, 'runmem' => $runmem, 'startmem' => $startmem, 'runnoswap' => $runnoswap, 'startnoswap' => $startnoswap, 'factor' => $opt::factor || 1, 'recheck' => $opt::recheck || 1, 'runtime' => $opt::recheck || 1, 'over_run_limit' => 1, 'over_start_limit' => 1, 'verbose' => $opt::verbose, }, ref($class) || $class; } sub over_run_limit { my $self = shift; my $status = 0; if($self->{'runmem'}) { # mem should be between 0-10ish # 100% available => 0 (1-1) # 50% available => 1 (2-1) # 10% available => 9 (10-1) my $mem = $self->mem_status(); ::debug("Run memory: $self->{'runmem'}/$mem\n"); $status += (::max(1,$self->{'runmem'}/$mem)-1); } if($self->{'runload'}) { # If used with other limits load should be between 0-10ish no warnings 'numeric'; my $load = $self->load_status(); if($self->{'runload'} > 0) { # Stop if the load is above the limit $status += ::max(0,$load - $self->{'runload'}); } else { # Stop if the load is below the limit (for sensor) $status += ::max(0,-$load - $self->{'runload'}); } } if($self->{'runnoswap'}) { # swap should be between 0-10ish # swap in or swap out or no swap = 0 # else log(swapin*swapout) my $swap = $self->swap_status(); $status += log(::max(1, $swap - $self->{'runnoswap'})); } if($self->{'runio'}) { my $io = $self->io_status(); $status += ::max(0,$io - $self->{'runio'}); } $self->{'over_run_limit'} = $status; if(not $opt::recheck) { $self->{'recheck'} = $self->{'factor'} * $self->{'over_run_limit'}; } ::debug("over_run_limit: $status\n"); return $self->{'over_run_limit'}; } sub over_start_limit { my $self = shift; my $status = 0; if($self->{'startmem'}) { # mem should be between 0-10ish # 100% available => 0 (1-1) # 50% available => 1 (2-1) # 10% available => 9 (10-1) my $mem = $self->mem_status(); ::debug("Start memory: $self->{'startmem'}/$mem\n"); $status += (::max(1,$self->{'startmem'}/$mem)-1); } if($self->{'startload'}) { # load should be between 0-10ish # 0 load => 0 no warnings 'numeric'; my $load = $self->load_status(); if($self->{'startload'} > 0) { # Stop if the load is above the limit $status += ::max(0,$load - $self->{'startload'}); } else { # Stop if the load is below the limit (for sensor) $status += ::max(0,-$load - $self->{'startload'}); } } if($self->{'startnoswap'}) { # swap should be between 0-10ish # swap in or swap out or no swap = 0 # else log(swapin*swapout) my $swap = $self->swap_status(); $status += log(::max(1, $swap - $self->{'startnoswap'})); } if($self->{'startio'}) { my $io = $self->io_status(); $status += ::max(0,$io - $self->{'startio'}); } $self->{'over_start_limit'} = $status; if(not $opt::recheck) { $self->{'recheck'} = $self->{'factor'} * $self->{'over_start_limit'}; } ::debug("over_start_limit: $status\n"); return $self->{'over_start_limit'}; } sub hard { my $self = shift; return $self->{'hard'}; } sub verbose { my $self = shift; return $self->{'verbose'}; } sub sleep_for_recheck { my $self = shift; if($self->{'recheck'} < 0.5) { # Never sleep less than 0.5 sec $self->{'recheck'} = 0.5; } if($self->verbose()) { $self->{'recheck'} = int($self->{'recheck'}*100)/100; print "Sleeping $self->{'recheck'}s\n"; } ::debug("recheck in $self->{'recheck'}s\n"); ::usleep(1); # For some reason this gets interrupted ::usleep(1000*$self->{'recheck'}); } sub sleep_while_running { my $self = shift; ::debug("check in $self->{'runtime'}s\n"); if($self->verbose()) { $self->{'runtime'} = int($self->{'runtime'}*100)/100; print "Running $self->{'runtime'}s\n"; } ::usleep(1); # For some reason this gets interrupted ::usleep(1000*$self->{'runtime'}); } sub nonblockGetLines { # An non-blocking filehandle read that returns an array of lines read # Returns: ($eof,@lines) # Example: --sensor 'vmstat 1 | perl -ane '\''$|=1; 4..0 and print $F[8],"\n"'\' my ($fh,$timeout) = @_; $timeout = 0 unless defined $timeout; my $rfd = ''; $::nonblockGetLines_last{$fh} = '' unless defined $::nonblockGetLines_last{$fh}; vec($rfd,fileno($fh),1) = 1; return unless select($rfd, undef, undef, $timeout)>=0; # I'm not sure the following is necessary? return unless vec($rfd,fileno($fh),1); my $buf = ''; my $n = sysread($fh,$buf,1024*1024); my $eof = eof($fh); # If we're done, make sure to send the last unfinished line return ($eof,$::nonblockGetLines_last{$fh}) unless $n; # Prepend the last unfinished line $buf = $::nonblockGetLines_last{$fh}.$buf; # And save any newly unfinished lines $::nonblockGetLines_last{$fh} = (substr($buf,-1) !~ /[\r\n]/ && $buf =~ s/([^\r\n]*)$//) ? $1 : ''; $buf ? ($eof,split(/\n/,$buf)) : ($eof); } sub read_sensor { my $self = shift; ::debug("read_sensor"); my $fh = $self->{'sensor_fh'}; if(not $fh) { # Start the sensor open($fh, "-|", $opt::sensor) || ::die_bug("Cannot open: $opt::sensor"); $self->{'sensor_fh'} = $fh; } # Read as much as we can (non_block) my ($eof,@lines) = nonblockGetLines($fh); # new load = last full line foreach my $line (@lines) { if(defined $line) { ::debug("Pipe saw: $eof [$line]\n"); $Global::last_sensor_reading = $line; } } if($eof) { # End of file => Restart the sensor close $fh; open($fh, "-|", $opt::sensor) || ::die_bug("Cannot open: $opt::sensor"); $self->{'sensor_fh'} = $fh; } return $Global::last_sensor_reading; } sub load_status { # Returns: # loadavg or sensor measurement my $self = shift; if($opt::sensor) { if(not defined $self->{'load_status'} or $self->{'load_status_cache_time'} + $self->{'recheck'} < time) { $self->{'load_status'} = $self->read_sensor(); while (not defined $self->{'load_status'}) { sleep 1; $self->{'load_status'} = $self->read_sensor(); } $self->{'load_status_cache_time'} = time - 0.001; } } else { # Normal load avg # Cache for some seconds if(not defined $self->{'load_status'} or $self->{'load_status_cache_time'} + $self->{'recheck'} < time) { $self->{'load_status'} = load_status_linux() if $^O ne 'darwin'; $self->{'load_status'} = load_status_darwin() if $^O eq 'darwin'; $self->{'load_status_cache_time'} = time; } } ::debug("load_status: ".$self->{'load_status'}."\n"); return $self->{'load_status'}; } sub undef_as_zero { my $a = shift; return $a ? $a : 0; } sub load_status_linux { my ($loadavg); if(open(IN,"/proc/loadavg")) { # Linux specific (but fast) my $upString = ; if($upString =~ m/^(\d+\.\d+)/) { $loadavg = $1; } else { ::die_bug("proc_loadavg"); } close IN; } elsif (open(IN,"uptime|")) { my $upString = ; if($upString =~ m/averages?.\s*(\d+\.\d+)/) { $loadavg = $1; } else { ::die_bug("uptime"); } close IN; } return $loadavg; } sub load_status_darwin { my $loadavg = `sysctl vm.loadavg`; if($loadavg =~ /vm\.loadavg: { ([0-9.]+) ([0-9.]+) ([0-9.]+) }/) { $loadavg = $1; } elsif (open(IN,"LANG=C uptime|")) { my $upString = ; if($upString =~ m/averages?.\s*(\d+\.\d+)/) { $loadavg = $1; } else { ::die_bug("uptime"); } close IN; } return $loadavg; } sub swap_status { # Returns: # (swap in)*(swap out) kb my $self = shift; my $status; # Cache for some seconds if(not defined $self->{'swap_status'} or $self->{'swap_status_cache_time'}+$self->{'recheck'} < time) { $status = swap_status_linux() if $^O ne 'darwin'; $status = swap_status_darwin() if $^O eq 'darwin'; $self->{'swap_status'} = ::max($status,0); $self->{'swap_status_cache_time'} = time; } ::debug("swap_status: $self->{'swap_status'}\n"); return $self->{'swap_status'}; } sub swap_status_linux { my $swap_activity; $swap_activity = "vmstat 1 2 | tail -n1 | awk '{print \$7*\$8}'"; # Run swap_activity measuring. return qx{ $swap_activity }; } sub swap_status_darwin { # Mach Virtual Memory Statistics: (page size of 4096 bytes, cache hits 0%) # free active spec inactive wire faults copy 0fill reactive pageins pageout # 298987 251463 162637 69437 265724 29730558 299022 2308237 1 110058 0 # 298991 251479 162637 69437 265726 43 4 16 0 0 0 my ($pagesize, $pageins, $pageouts); my @vm_stat = `vm_stat 1 | head -n4`; $pagesize = $1 if $vm_stat[0] =~ m/page size of (\d+) bytes/; $pageins = (split(/\s+/,$vm_stat[3]))[9]; $pageouts = (split(/\s+/,$vm_stat[3]))[10]; return ($pageins*$pageouts*$pagesize)/1024; } sub mem_status { # Returns: # number of bytes (free+cache) my $self = shift; # Cache for one second if(not defined $self->{'mem_status'} or $self->{'mem_status_cache_time'}+$self->{'recheck'} < time) { $self->{'mem_status'} = mem_status_linux() if $^O ne 'darwin'; $self->{'mem_status'} = mem_status_darwin() if $^O eq 'darwin'; $self->{'mem_status_cache_time'} = time; } ::debug("mem_status: $self->{'mem_status'}\n"); return $self->{'mem_status'}; } sub mem_status_linux { # total used free shared buffers cached # Mem: 3366496 2901664 464832 0 179228 1850692 # -/+ buffers/cache: 871744 2494752 # Swap: 6445476 1396860 5048616 my @free = `free`; my $free = (split(/\s+/,$free[2]))[3]; return $free*1024; } sub mem_status_darwin { # Mach Virtual Memory Statistics: (page size of 4096 bytes, cache hits 0%) # free active spec inactive wire faults copy 0fill reactive pageins pageout # 298987 251463 162637 69437 265724 29730558 299022 2308237 1 110058 0 # 298991 251479 162637 69437 265726 43 4 16 0 0 0 my ($pagesize, $pages_free, $pages_speculative); my @vm_stat = `vm_stat 1 | head -n4`; $pagesize = $1 if $vm_stat[0] =~ m/page size of (\d+) bytes/; $pages_free = (split(/\s+/,$vm_stat[3]))[0]; $pages_speculative = (split(/\s+/,$vm_stat[3]))[2]; return ($pages_free+$pages_speculative)*$pagesize; } sub io_status { # Returns: # max percent for all devices my $self = shift; # Cache for one second if(not defined $self->{'io_status'} or $self->{'io_status_cache_time'}+$self->{'recheck'} < time) { $self->{'io_status'} = io_status_linux() if $^O ne 'darwin'; $self->{'io_status'} = io_status_darwin() if $^O eq 'darwin'; $self->{'io_status_cache_time'} = time; } ::debug("io_status: $self->{'io_status'}\n"); return $self->{'io_status'}; } sub io_status_linux { # Device: rrqm/s wrqm/s r/s w/s rkB/s wkB/s avgrq-sz avgqu-sz await r_await w_await svctm %util # sda 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 my @iostat_out = `LANG=C iostat -x 1 2`; # throw away all execpt the last Device:-section my @iostat; for(reverse @iostat_out) { /Device:/ and last; push @iostat, (split(/\s+/,$_))[13]; } my $io = ::max(@iostat); return undef_as_zero($io)/10; } sub io_status_darwin { # disk0 disk1 disk2 # KB/t tps MB/s KB/t tps MB/s KB/t tps MB/s # 14.95 15 0.22 11.18 35 0.38 2.00 0 0.00 # 0.00 0 0.00 0.00 0 0.00 0.00 0 0.00 my @iostat_out = `LANG=C iostat -d -w 1 -c 2`; # return the MB/s of the last second (not the %util) my @iostat = split(/\s+/, $iostat_out[3]); my $io = $iostat[3] + $iostat[6] + $iostat[9]; return ::min($io, 10); } $::exitsignal = $::exitstatus = 0; # Dummy