#! /usr/perl5/bin/perl # # CDDL HEADER START # # The contents of this file are subject to the terms of the # Common Development and Distribution License (the "License"). # You may not use this file except in compliance with the License. # # You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE # or http://www.opensolaris.org/os/licensing. # See the License for the specific language governing permissions # and limitations under the License. # # When distributing Covered Code, include this CDDL HEADER in each # file and include the License file at usr/src/OPENSOLARIS.LICENSE. # If applicable, add the following below this CDDL HEADER, with the # fields enclosed by brackets "[]" replaced with your own identifying # information: Portions Copyright [yyyy] [name of copyright owner] # # CDDL HEADER END # # # Copyright 2008 Sun Microsystems, Inc. All rights reserved. # Use is subject to license terms. # # ident "%Z%%M% %I% %E% SMI" # # # lgrpinfo: display information about locality groups. # require 5.6.1; use warnings; use strict; use Getopt::Long qw(:config no_ignore_case bundling auto_version); use File::Basename; # Sun::Solaris::Kstat is used to extract per-lgroup load average. use Sun::Solaris::Kstat; use POSIX qw(locale_h); use Sun::Solaris::Utils qw(textdomain gettext); use Sun::Solaris::Lgrp ':CONSTANTS'; use constant KB => 1024; # # Amount of load contributed by a single thread. The value is exported by the # kernel in the 'loadscale' variable of lgroup kstat, but in case it is missing # we use the current default value as the best guess. # use constant LGRP_LOADAVG_THREAD_MAX => 65516; # Get script name our $cmdname = basename($0, ".pl"); # Get liblgrp version my $version = Sun::Solaris::Lgrp::lgrp_version(); our $VERSION = "%I% (liblgrp version $version)"; # The $loads hash keeps per-lgroup load average. our $loads = {}; ######################################## # Main body ## # Set message locale setlocale(LC_ALL, ""); textdomain(TEXT_DOMAIN); # Parse command-line options our($opt_a, $opt_l, $opt_m, $opt_c, $opt_C, $opt_e, $opt_t, $opt_h, $opt_u, $opt_r, $opt_L, $opt_P, $opt_I, $opt_T, $opt_G); GetOptions("a" => \$opt_a, "c" => \$opt_c, "C" => \$opt_C, "e" => \$opt_e, "G" => \$opt_G, "h|?" => \$opt_h, "l" => \$opt_l, "L" => \$opt_L, "I" => \$opt_I, "m" => \$opt_m, "r" => \$opt_r, "t" => \$opt_t, "T" => \$opt_T, "u=s" => \$opt_u, "P" => \$opt_P) || usage(3); usage(0) if $opt_h; # Check for conflicting options my $nfilters = 0; $nfilters++ if $opt_C; $nfilters++ if $opt_P; $nfilters++ if $opt_T; if ($nfilters > 1) { printf STDERR gettext("%s: Options -C, -T and -P can not be used together\n"), $cmdname; usage(3); } if ($opt_T && ($opt_I || $opt_t)) { printf STDERR gettext("%s: Option -T can not be used with -I, -t\n"), $cmdname; usage(3); } if ($opt_T && scalar @ARGV) { printf STDERR gettext("%s: Warning: with '-T' all lgroups on the command line "), $cmdname; printf STDERR gettext("are ignored\n\n"); } if ($opt_L && $opt_I) { printf STDERR gettext("%s: Option -I can not be used with -L\n"), $cmdname; usage(3); } # Figure out what to do based on options my $do_default = 1 unless $opt_a || $opt_l || $opt_m || $opt_c || $opt_e || $opt_t || $opt_r; my $l = Sun::Solaris::Lgrp->new($opt_G ? LGRP_VIEW_OS : LGRP_VIEW_CALLER) or die(gettext("$cmdname: can not get lgroup information from the system\n")); # Get list of all lgroups, the root and the list of intermediates my @lgrps = nsort($l->lgrps); my $root = $l->root; my @intermediates = grep { $_ != $root && !$l->isleaf($_) } @lgrps; my $is_uma = (scalar @lgrps == 1); # Print everything if -a is specified or it is default without -T my $do_all = 1 if $opt_a || ($do_default && !($opt_T || $opt_L)); # Print individual information if do_all or requested specific print my $do_lat = 1 if $do_all || $opt_l; my $do_memory = 1 if $do_all || $opt_m; my $do_cpu = 1 if $do_all || $opt_c; my $do_topo = 1 if $do_all || $opt_t; my $do_rsrc = 1 if $do_all || $opt_r; my $do_load = 1 if $do_all || $opt_e; my $do_table = 1 if $opt_a || $opt_L; my $do_something = ($do_lat || $do_memory || $do_cpu || $do_topo || $do_rsrc || $do_load); # Does the liblgrp(3LIB) has enough capabilities to support resource view? if ($do_rsrc && LGRP_VER_CURRENT == 1) { if ($opt_r) { printf STDERR gettext("%s: sorry, your system does not support"), $cmdname; printf STDERR " lgrp_resources(3LGRP)\n"; } $do_rsrc = 0; } # Get list of lgrps from arguments, expanding symbolic names like # "root" and "leaves" # Use all lgroups if none are specified on the command line my @lgrp_list = (scalar (@ARGV) && !$opt_T) ? lgrp_expand($l, @ARGV) : @lgrps; # Apply 'Parent' or 'Children' operations if requested @lgrp_list = map { $l->parents($_) } @lgrp_list if $opt_P; @lgrp_list = map { $l->children($_) } @lgrp_list if $opt_C; # Drop repeating elements and sort lgroups numerically. @lgrp_list = uniqsort(@lgrp_list); # If both -L and -c are specified, just print list of CPUs. if ($opt_c && $opt_I) { my @cpus = uniqsort(map { $l->cpus($_, LGRP_CONTENT_HIERARCHY) } @lgrp_list); print "@cpus\n"; exit(0); } my $unit_str = "K"; my $units = KB; # Convert units to canonical numeric and string formats. if ($opt_u) { if ($opt_u =~ /^b$/i) { $units = 1; $unit_str = "B"; } elsif ($opt_u =~ /^k$/i) { $units = KB; $unit_str = "K"; } elsif ($opt_u =~ /^m$/i) { $units = KB * KB; $unit_str = "M"; } elsif ($opt_u =~ /^g$/i) { $units = KB * KB * KB; $unit_str = "G"; } elsif ($opt_u =~ /^t$/i) { $units = KB * KB * KB * KB; $unit_str = "T"; } elsif ($opt_u =~ /^p$/i) { $units = KB * KB * KB * KB * KB; $unit_str = "P"; } elsif ($opt_u =~ /^e$/i) { $units = KB * KB * KB * KB * KB * KB; $unit_str = "E"; } elsif (! ($opt_u =~ /^m$/i)) { printf STDERR gettext("%s: invalid unit '$opt_u', should be [b|k|m|g|t|p|e]"), $cmdname; printf STDERR gettext(", using the default.\n\n"); $opt_u = 0; } } # Collect load average data if requested. $loads = get_lav() if $do_load; # Get latency values for each lgroup. my %self_latencies; map { $self_latencies{$_} = $l->latency($_, $_) } @lgrps; # If -T is specified, just print topology and return. if ($opt_T) { lgrp_prettyprint($l); print_latency_table(\@lgrps, \@lgrps) if $do_table; exit(0); } if (!scalar @lgrp_list) { printf STDERR gettext("%s: No matching lgroups found!\n"), $cmdname; exit(2); } # Just print list of lgrps if doing just filtering (print "@lgrp_list\n"), exit 0 if $opt_I; if ($do_something) { # Walk through each requested lgrp and print whatever is requested. foreach my $lgrp (@lgrp_list) { my $is_leaf = $l->isleaf($lgrp); my ($children, $parents, $cpus, $memstr, $rsrc); my $prefix = ($lgrp == $root) ? "root": $is_leaf ? gettext("leaf") : gettext("intermediate"); printf gettext("lgroup %d (%s):"), $lgrp, $prefix; if ($do_topo) { # Get children of this lgrp. my @children = $l->children($lgrp); $children = $is_leaf ? gettext("Children: none") : gettext("Children: ") . lgrp_collapse(@children); # Are there any parents for this lgrp? my @parents = $l->parents($lgrp); $parents = @parents ? gettext(", Parent: ") . "@parents" : ""; } if ($do_cpu) { $cpus = lgrp_showcpus($lgrp, LGRP_CONTENT_HIERARCHY); } if ($do_memory) { $memstr = lgrp_showmemory($lgrp, LGRP_CONTENT_HIERARCHY); } if ($do_rsrc) { $rsrc = lgrp_showresources($lgrp); } # Print all the information about lgrp. print "\n\t$children$parents" if $do_topo; print "\n\t$cpus" if $do_cpu && $cpus; print "\n\t$memstr" if $do_memory && $memstr; print "\n\t$rsrc" if $do_rsrc; print "\n\t$loads->{$lgrp}" if defined ($loads->{$lgrp}); if ($do_lat && defined($self_latencies{$lgrp})) { printf gettext("\n\tLatency: %d"), $self_latencies{$lgrp}; } print "\n"; } } print_latency_table(\@lgrps, \@lgrp_list) if $do_table; exit 0; # # usage(exit_status) # print usage message and exit with the specified exit status. # sub usage { printf STDERR gettext("Usage:\t%s"), $cmdname; print STDERR " [-aceGlLmrt] [-u unit] [-C|-P] [lgrp] ...\n"; print STDERR " \t$cmdname -I [-c] [-G] [-C|-P] [lgrp] ...\n"; print STDERR " \t$cmdname -T [-aceGlLmr] [-u unit]\n"; print STDERR " \t$cmdname -h\n\n"; printf STDERR gettext(" Display information about locality groups\n\n" . "\t-a: Equivalent to \"%s\" without -T and to \"%s\" with -T\n"), "-celLmrt", "-celLmr"; print STDERR gettext("\t-c: Print CPU information\n"), gettext("\t-C: Children of the specified lgroups\n"), gettext("\t-e: Print lgroup load average\n"), gettext("\t-h: Print this message and exit\n"), gettext("\t-I: Print lgroup or CPU IDs only\n"), gettext("\t-l: Print information about lgroup latencies\n"), gettext("\t-G: Print OS view of lgroup hierarchy\n"), gettext("\t-L: Print lgroup latency table\n"), gettext("\t-m: Print memory information\n"), gettext("\t-P: Parent(s) of the specified lgroups\n"), gettext("\t-r: Print lgroup resources\n"), gettext("\t-t: Print information about lgroup topology\n"), gettext("\t-T: Print the hierarchy tree\n"), gettext("\t-u unit: Specify memory unit (b,k,m,g,t,p,e)\n\n\n"); print STDERR gettext(" The lgrp may be specified as an lgroup ID,"), gettext(" \"root\", \"all\",\n"), gettext(" \"intermediate\" or \"leaves\".\n\n"); printf STDERR gettext(" The default set of options is \"%s\"\n\n"), "-celmrt all"; print STDERR gettext(" Without any options print topology, CPU and memory " . "information about each\n" . " lgroup. If any lgroup IDs are specified on the " . "command line only print\n" . " information about the specified lgroup.\n\n"); exit(shift); } # Return the input list with duplicates removed. sub uniq { my %seen; return (grep { ++$seen{$_} == 1 } @_); } # # Sort the list numerically # Should be called in list context # sub nsort { return (sort { $a <=> $b } @_); } # # Sort list numerically and remove duplicates # Should be called in list context # sub uniqsort { return (sort { $a <=> $b } uniq(@_)); } # Round values sub round { my $val = shift; return (int($val + 0.5)); } # # Expand list of lgrps. # Translate 'root' to the root lgrp id # Translate 'all' to the list of all lgrps # Translate 'leaves' to the list of all lgrps' # Translate 'intermediate' to the list of intermediates. # sub lgrp_expand { my $lobj = shift; my %seen; my @result; # create a hash element for every element in @lgrps map { $seen{$_}++ } @lgrps; foreach my $lgrp (@_) { push(@result, $lobj->root), next if $lgrp =~ m/^root$/i; push(@result, @lgrps), next if $lgrp =~ m/^all$/i; push(@result, $lobj->leaves), next if $lgrp =~ m/^leaves$/i; push(@result, @intermediates), next if $lgrp =~ m/^intermediate$/i; push(@result, $lgrp), next if $lgrp =~ m/^\d+$/ && $seen{$lgrp}; printf STDERR gettext("%s: skipping invalid lgrp $lgrp\n"), $cmdname; } return @result; } # # lgrp_tree(class, node) # # Build the tree of the lgroup hierarchy starting with the specified node or # root if no initial node is specified. Calls itself recursively specifying each # of the children as a starting node. Builds a reference to the list with the # node in the end and each element being a subtree. # sub lgrp_tree { my $c = shift; my $lgrp = shift || $c->root; # Call itself for each of the children and combine results in a list. [ (map { lgrp_tree($c, $_) } $c->children($lgrp)), $lgrp ]; } # # lgrp_pp(tree, prefix, childprefix, npeers) # # pretty-print the hierarchy tree. # Input Arguments: # Reference to the tree # Prefix for me to use # Prefix for my children to use # Number of peers left # sub lgrp_pp { my $tree = shift; my $myprefix = shift; my $childprefix = shift; my $npeers = shift; my $el = pop @$tree; my $nchildren = scalar @$tree; my $printprefix = "$childprefix"; my $printpostfix = $npeers ? "| " : " "; return unless defined ($el); my $bar = $npeers ? "|" : "`"; print $childprefix ? $childprefix : ""; print $myprefix ? "$bar" . "-- " : ""; lgrp_print($el, "$printprefix$printpostfix"); my $new_prefix = $npeers ? $myprefix : " "; # Pretty-print the subtree with a new offset. map { lgrp_pp($_, "| ", "$childprefix$new_prefix", --$nchildren) } @$tree; } # Pretty print the whole tree sub lgrp_prettyprint { my $c = shift; my $tree = lgrp_tree $c; lgrp_pp($tree, '', '', scalar $tree - 1); } sub lgrp_print { my $lgrp = shift; my $prefix = shift; my ($cpus, $memstr, $rsrc); my $is_interm = ($lgrp != $root && !$l->isleaf($lgrp)); my $not_root = $is_uma || $lgrp != $root; print "$lgrp"; if ($do_cpu && $not_root) { $cpus = lgrp_showcpus($lgrp, LGRP_CONTENT_HIERARCHY); } if ($do_memory && $not_root) { $memstr = lgrp_showmemory($lgrp, LGRP_CONTENT_HIERARCHY); } if ($do_rsrc && ($is_uma || $is_interm)) { $rsrc = lgrp_showresources($lgrp) if $do_rsrc; } # Print all the information about lgrp. print "\n$prefix$cpus" if $cpus; print "\n$prefix$memstr" if $memstr; print "\n$prefix$rsrc" if $rsrc; print "\n$prefix$loads->{$lgrp}" if defined ($loads->{$lgrp}); # Print latency information if requested. if ($do_lat && $lgrp != $root && defined($self_latencies{$lgrp})) { print "\n${prefix}"; printf gettext("Latency: %d"), $self_latencies{$lgrp}; } print "\n"; } # What CPUs are in this lgrp? sub lgrp_showcpus { my $lgrp = shift; my $hier = shift; my @cpus = $l->cpus($lgrp, $hier); my $ncpus = @cpus; return 0 unless $ncpus; # Sort CPU list if there is something to sort. @cpus = nsort(@cpus) if ($ncpus > 1); my $cpu_string = lgrp_collapse(@cpus); return (($ncpus == 1) ? gettext("CPU: ") . $cpu_string: gettext("CPUs: ") . $cpu_string); } # How much memory does this lgrp contain? sub lgrp_showmemory { my $lgrp = shift; my $hier = shift; my $memory = $l->mem_size($lgrp, LGRP_MEM_SZ_INSTALLED, $hier); return (0) unless $memory; my $freemem = $l->mem_size($lgrp, LGRP_MEM_SZ_FREE, $hier) || 0; my $memory_r = memory_to_string($memory); my $freemem_r = memory_to_string($freemem); my $usedmem = memory_to_string($memory - $freemem); my $memstr = sprintf(gettext("Memory: installed %s"), $memory_r); $memstr = $memstr . sprintf(gettext(", allocated %s"), $usedmem); $memstr = $memstr . sprintf(gettext(", free %s"), $freemem_r); return ($memstr); } # Get string containing lgroup resources sub lgrp_showresources { my $lgrp = shift; my $rsrc_prefix = gettext("Lgroup resources:"); # What resources does this lgroup contain? my @resources_cpu = nsort($l->resources($lgrp, LGRP_RSRC_CPU)); my @resources_mem = nsort($l->resources($lgrp, LGRP_RSRC_MEM)); my $rsrc = @resources_cpu || @resources_mem ? "" : gettext("none"); $rsrc = $rsrc_prefix . $rsrc; my $rsrc_cpu = lgrp_collapse(@resources_cpu); my $rsrc_mem = lgrp_collapse(@resources_mem); my $lcpu = gettext("CPU"); my $lmemory = gettext("memory"); $rsrc = "$rsrc $rsrc_cpu ($lcpu);" if scalar @resources_cpu; $rsrc = "$rsrc $rsrc_mem ($lmemory)" if scalar @resources_mem; return ($rsrc); } # # Consolidate consequtive ids as start-end # Input: list of ids # Output: string with space-sepated cpu values with ranges # collapsed as x-y # sub lgrp_collapse { return ('') unless @_; my @args = uniqsort(@_); my $start = shift(@args); my $result = ''; my $end = $start; # Initial range consists of the first element foreach my $el (@args) { if ($el == ($end + 1)) { # # Got consecutive ID, so extend end of range without # printing anything since the range may extend further # $end = $el; } else { # # Next ID is not consecutive, so print IDs gotten so # far. # if ($end > $start + 1) { # range $result = "$result $start-$end"; } elsif ($end > $start) { # different values $result = "$result $start $end"; } else { # same value $result = "$result $start"; } # Try finding consecutive range starting from this ID $start = $end = $el; } } # Print last ID(s) if ($end > $start + 1) { $result = "$result $start-$end"; } elsif ($end > $start) { $result = "$result $start $end"; } else { $result = "$result $start"; } # Remove any spaces in the beginning $result =~ s/^\s+//; return ($result); } # Print latency information if requested and the system has several lgroups. sub print_latency_table { my ($lgrps1, $lgrps2) = @_; return unless scalar @lgrps; # Find maximum lgroup my $max = $root; map { $max = $_ if $max < $_ } @$lgrps1; # Field width for lgroup - the width of the largest lgroup and 1 space my $lgwidth = length($max) + 1; # Field width for latency. Get the maximum latency and add 1 space. my $width = length($l->latency($root, $root)) + 1; # Make sure that width is enough to print lgroup itself. $width = $lgwidth if $width < $lgwidth; # Print table header print gettext("\nLgroup latencies:\n"); # Print horizontal line print "\n", "-" x ($lgwidth + 1); map { print '-' x $width } @$lgrps1; print "\n", " " x $lgwidth, "|"; map { printf("%${width}d", $_) } @$lgrps1; print "\n", "-" x ($lgwidth + 1); map { print '-' x $width } @$lgrps1; print "\n"; # Print the latency table foreach my $l1 (@$lgrps2) { printf "%-${lgwidth}d|", $l1; foreach my $l2 (@lgrps) { my $latency = $l->latency($l1, $l2); if (!defined ($latency)) { printf "%${width}s", "-"; } else { printf "%${width}d", $latency; } } print "\n"; } # Print table footer print "-" x ($lgwidth + 1); map { print '-' x $width } @lgrps; print "\n"; } # # Convert a number to a string representation # The number is scaled down until it is small enough to be in a good # human readable format i.e. in the range 0 thru 1023. # If it's smaller than 10 there's room enough to provide one decimal place. # sub number_to_scaled_string { my $number = shift; my $scale = KB; my @measurement = ('K', 'M', 'G', 'T', 'P', 'E'); # Measurement my $uom = shift(@measurement); my $result; my $save = $number; # Get size in K. $number /= KB; while (($number >= $scale) && $uom ne 'E') { $uom = shift(@measurement); $save = $number; $number /= $scale; } # check if we should output a decimal place after the point if ($save && (($save / $scale) < 10)) { $result = sprintf("%2.1f", $save / $scale); } else { $result = round($number); } return ("$result$uom"); } # # Convert memory size to the string representation # sub memory_to_string { my $number = shift; # Zero memory - just print 0 return ("0$unit_str") unless $number; # # Return memory size scaled to human-readable form unless -u is # specified. # return (number_to_scaled_string($number)) unless $opt_u; my $scaled = $number / $units; my $result; if ($scaled < 0.1) { $result = sprintf("%2.1g", $scaled); } elsif ($scaled < 10) { $result = sprintf("%2.1f", $scaled); } else { $result = int($scaled + 0.5); } return ("$result$unit_str"); } # # Read load averages from lgrp kstats Return hash reference indexed by lgroup ID # for each lgroup which has load information. # sub get_lav { my $load = {}; my $ks = Sun::Solaris::Kstat->new(strip_strings => 1) or warn(gettext("$cmdname: kstat_open() failed: %!\n")), return $load; my $lgrp_kstats = $ks->{lgrp} or warn(gettext("$cmdname: can not read lgrp kstat\n)")), return $load; # Collect load for each lgroup foreach my $i (keys %$lgrp_kstats) { next unless $lgrp_kstats->{$i}->{"lgrp$i"}; my $lav = $lgrp_kstats->{$i}->{"lgrp$i"}->{"load average"}; # Skip this lgroup if can't find its load average next unless defined $lav; my $scale = $lgrp_kstats->{$i}->{"lgrp$i"}->{"loadscale"} || LGRP_LOADAVG_THREAD_MAX; $load->{$i} = sprintf (gettext("Load: %4.3g"), $lav / $scale); } return $load; }