#
# This is not a runnable script, it is a Perl module, a collection of variables, subroutines, etc.
# To get help about exported variables and subroutines, execute the following command:
#
# perldoc Uname.pm
#
# or see POD (Plain Old Documentation) embedded to the source...
#
#
#//===----------------------------------------------------------------------===//
#//
#// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
#// See https://llvm.org/LICENSE.txt for license information.
#// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
#//
#//===----------------------------------------------------------------------===//
#
package Uname;
use strict;
use warnings;
use warnings::register;
use Exporter;
use POSIX;
use File::Glob ":glob";
use Net::Domain qw{};
# Following code does not work with Perl 5.6 on Linux* OS and Windows* OS:
#
# use if $^O eq "darwin", tools => qw{};
#
# The workaround for Perl 5.6:
#
BEGIN {
if ( $^O eq "darwin" or $^O eq "linux" ) {
require tools;
import tools;
}; # if
if ( $^O eq "MSWin32" ) {
require Win32;
}; # if
}; # BEGIN
my $mswin = qr{\A(?:MSWin32|Windows_NT)\z};
my @posix = qw{ kernel_name fqdn kernel_release kernel_version machine };
# Properties supported by POSIX::uname().
my @linux =
qw{ processor hardware_platform operating_system };
# Properties reported by uname in Linux* OS.
my @base = ( @posix, @linux );
# Base properties.
my @aux =
(
qw{ host_name domain_name },
map( "operating_system_$_", qw{ name release codename description } )
);
# Auxiliary properties.
my @all = ( @base, @aux );
# All the properties.
my @meta = qw{ base_names all_names value };
# Meta functions.
our $VERSION = "0.07";
our @ISA = qw{ Exporter };
our @EXPORT = qw{};
our @EXPORT_OK = ( @all, @meta );
our %EXPORT_TAGS =
(
base => [ @base ],
all => [ @all ],
meta => [ @meta ],
);
my %values;
# Hash of values. Some values are strings, some may be references to code which should be
# evaluated to get real value. This trick is implemented because call to Net::Domain::hostfqdn()
# is relatively slow.
# Get values from POSIX::uname().
@values{ @posix } = POSIX::uname();
# On some systems POSIX::uname() returns "short" node name (without domain name). To be consistent
# on all systems, we will get node name from alternative source.
if ( $^O =~ m/cygwin/i ) {
# Function from Net::Domain module works well, but on Cygwin it prints to
# stderr "domainname: not found". So we will use environment variables for now.
$values{ fqdn } = lc( $ENV{ COMPUTERNAME } . "." . $ENV{ USERDNSDOMAIN } );
} else {
# On systems other than Cygwin, let us use Net::Domain::hostfqdn(), but do it only node name
# is really requested.
$values{ fqdn } =
sub {
my $fqdn = Net::Domain::hostfqdn(); # "fqdn" stands for "fully qualified domain name".
# On some systems POSIX::uname() and Net::Domain::hostfqdn() reports different names.
# Let us issue a warning if they significantly different. Names are insignificantly
# different if POSIX::uname() matches the beginning of Net::Domain::hostfqdn().
if (
$fqdn eq substr( $fqdn, 0, length( $fqdn ) )
&&
(
length( $fqdn ) == length( $fqdn )
||
substr( $fqdn, length( $fqdn ), 1 ) eq "."
)
) {
# Ok.
} else {
warnings::warnif(
"POSIX::uname() and Net::Domain::hostfqdn() reported different names: " .
"\"$values{ fqdn }\" and \"$fqdn\" respectively\n"
);
}; # if
return $fqdn;
}; # sub
}; # if
if ( $^O =~ $mswin ) {
if (
$values{ machine } =~ m{\A(?:x86|[56]86)\z}
and
exists( $ENV{ PROCESSOR_ARCHITECTURE } ) and $ENV{ PROCESSOR_ARCHITECTURE } eq "x86"
and
exists( $ENV{ PROCESSOR_ARCHITEW6432 } )
) {
if ( $ENV{ PROCESSOR_ARCHITEW6432 } eq "AMD64" ) {
$values{ machine } = "x86_64";
}; # if
}; # if
}; # if
# Some values are not returned by POSIX::uname(), let us compute them.
# processor.
$values{ processor } = $values{ machine };
# hardware_platform.
if ( 0 ) {
} elsif ( $^O eq "linux" or $^O eq "freebsd" or $^O eq "netbsd" ) {
if ( 0 ) {
} elsif ( $values{ machine } =~ m{\Ai[3456]86\z} ) {
$values{ hardware_platform } = "i386";
} elsif ( $values{ machine } =~ m{\A(x86_64|amd64)\z} ) {
$values{ hardware_platform } = "x86_64";
} elsif ( $values{ machine } =~ m{\Aarmv7\D*\z} ) {
$values{ hardware_platform } = "arm";
} elsif ( $values{ machine } =~ m{\Appc64le\z} ) {
$values{ hardware_platform } = "ppc64le";
} elsif ( $values{ machine } =~ m{\Appc64\z} ) {
$values{ hardware_platform } = "ppc64";
} elsif ( $values{ machine } =~ m{\Aaarch64\z} ) {
$values{ hardware_platform } = "aarch64";
} elsif ( $values{ machine } =~ m{\Amips64\z} ) {
$values{ hardware_platform } = "mips64";
} elsif ( $values{ machine } =~ m{\Amips\z} ) {
$values{ hardware_platform } = "mips";
} elsif ( $values{ machine } =~ m{\Ariscv64\z} ) {
$values{ hardware_platform } = "riscv64";
} else {
die "Unsupported machine (\"$values{ machine }\") returned by POSIX::uname(); stopped";
}; # if
} elsif ( $^O eq "darwin" ) {
if ( 0 ) {
} elsif ( $values{ machine } eq "x86" or $values{ machine } eq "i386" ) {
$values{ hardware_platform } =
sub {
my $platform = "i386";
# Some OSes on Intel(R) 64 still reports "i386" machine. Verify it by using
# the value returned by 'sysctl -n hw.optional.x86_64'. On Intel(R) 64-bit systems the
# value == 1; on 32-bit systems the 'hw.optional.x86_64' property either does not exist
# or the value == 0. The path variable does not contain a path to sysctl when
# started by crontab.
my $sysctl = ( which( "sysctl" ) or "/usr/sbin/sysctl" );
my $output;
debug( "Executing $sysctl..." );
execute( [ $sysctl, "-n", "hw.optional.x86_64" ], -stdout => \$output, -stderr => undef );
chomp( $output );
if ( 0 ) {
} elsif ( "$output" eq "" or "$output" eq "0" ) {
$platform = "i386";
} elsif ( "$output" eq "1" ) {
$platform = "x86_64";
} else {
die "Unsupported value (\"$output\") returned by \"$sysctl -n hw.optional.x86_64\"; stopped";
}; # if
return $platform;
}; # sub {
} elsif ( $values{ machine } eq "x86_64" ) {
# Some OS X* versions report "x86_64".
$values{ hardware_platform } = "x86_64";
} else {
die "Unsupported machine (\"$values{ machine }\") returned by POSIX::uname(); stopped";
}; # if
} elsif ( $^O =~ $mswin ) {
if ( 0 ) {
} elsif ( $values{ machine } =~ m{\A(?:x86|[56]86)\z} ) {
$values{ hardware_platform } = "i386";
} elsif ( $values{ machine } eq "x86_64" or $values{ machine } eq "amd64" ) {
# ActivePerl for IA-32 architecture returns "x86_64", while ActivePerl for Intel(R) 64 returns "amd64".
$values{ hardware_platform } = "x86_64";
} else {
die "Unsupported machine (\"$values{ machine }\") returned by POSIX::uname(); stopped";
}; # if
} elsif ( $^O eq "cygwin" ) {
if ( 0 ) {
} elsif ( $values{ machine } =~ m{\Ai[3456]86\z} ) {
$values{ hardware_platform } = "i386";
} elsif ( $values{ machine } eq "x86_64" ) {
$values{ hardware_platform } = "x86_64";
} else {
die "Unsupported machine (\"$values{ machine }\") returned by POSIX::uname(); stopped";
}; # if
} else {
die "Unsupported OS (\"$^O\"); stopped";
}; # if
# operating_system.
if ( 0 ) {
} elsif ( $values{ kernel_name } eq "Linux" ) {
$values{ operating_system } = "GNU/Linux";
my $release; # Name of chosen "*-release" file.
my $bulk; # Content of release file.
# On Ubuntu, lsb-release is quite informative, e. g.:
# DISTRIB_ID=Ubuntu
# DISTRIB_RELEASE=9.04
# DISTRIB_CODENAME=jaunty
# DISTRIB_DESCRIPTION="Ubuntu 9.04"
# Try lsb-release first. But on some older systems lsb-release is not informative.
# It may contain just one line:
# LSB_VERSION="1.3"
$release = "/etc/lsb-release";
if ( -e $release ) {
$bulk = read_file( $release );
} else {
$bulk = "";
}; # if
if ( $bulk =~ m{^DISTRIB_} ) {
# Ok, this lsb-release is informative.
$bulk =~ m{^DISTRIB_ID\s*=\s*(.*?)\s*$}m
or runtime_error( "$release: There is no DISTRIB_ID:", $bulk, "(eof)" );
$values{ operating_system_name } = $1;
$bulk =~ m{^DISTRIB_RELEASE\s*=\s*(.*?)\s*$}m
or runtime_error( "$release: There is no DISTRIB_RELEASE:", $bulk, "(eof)" );
$values{ operating_system_release } = $1;
$bulk =~ m{^DISTRIB_CODENAME\s*=\s*(.*?)\s*$}m
or runtime_error( "$release: There is no DISTRIB_CODENAME:", $bulk, "(eof)" );
$values{ operating_system_codename } = $1;
$bulk =~ m{^DISTRIB_DESCRIPTION\s*="?\s*(.*?)"?\s*$}m
or runtime_error( "$release: There is no DISTRIB_DESCRIPTION:", $bulk, "(eof)" );
$values{ operating_system_description } = $1;
} else {
# Oops. lsb-release is missed or not informative. Try other *-release files.
$release = "/etc/system-release";
if ( not -e $release ) { # Use /etc/system-release" if such file exists.
# Otherwise try other "/etc/*-release" files, but ignore "/etc/lsb-release".
my @releases = grep( $_ ne "/etc/lsb-release", bsd_glob( "/etc/*-release" ) );
# On some Fedora systems there are two files: fedora-release and redhat-release
# with identical content. If fedora-release present, ignore redjat-release.
if ( grep( $_ eq "/etc/fedora-release", @releases ) ) {
@releases = grep( $_ ne "/etc/redhat-release", @releases );
}; # if
if ( @releases == 1 ) {
$release = $releases[ 0 ];
} else {
if ( @releases == 0 ) {
# No *-release files found, try debian_version.
$release = "/etc/debian_version";
if ( not -e $release ) {
$release = undef;
warning( "No release files found in \"/etc/\" directory." );
}; # if
} else {
$release = undef;
warning( "More than one release files found in \"/etc/\" directory:", @releases );
}; # if
}; # if
}; # if
if ( defined( $release ) ) {
$bulk = read_file( $release );
if ( $release =~ m{system|redhat|fedora} ) {
# Red Hat or Fedora. Parse the first line of file.
# Typical values of *-release (one of):
# Red Hat Enterprise Linux* OS Server release 5.2 (Tikanga)
# Red Hat Enterprise Linux* OS AS release 3 (Taroon Update 4)
# Fedora release 10 (Cambridge)
$bulk =~ m{\A(.*)$}m
or runtime_error( "$release: Cannot find the first line:", $bulk, "(eof)" );
my $first_line = $1;
$values{ operating_system_description } = $first_line;
$first_line =~ m{\A(.*?)\s+release\s+(.*?)(?:\s+\((.*?)(?:\s+Update\s+(.*?))?\))?\s*$}
or runtime_error( "$release:1: Cannot parse line:", $first_line );
$values{ operating_system_name } = $1;
$values{ operating_system_release } = $2 . ( defined( $4 ) ? ".$4" : "" );
$values{ operating_system_codename } = $3;
} elsif ( $release =~ m{SuSE} ) {
# Typical SuSE-release:
# SUSE Linux* OS Enterprise Server 10 (x86_64)
# VERSION = 10
# PATCHLEVEL = 2
$bulk =~ m{\A(.*)$}m
or runtime_error( "$release: Cannot find the first line:", $bulk, "(eof)" );
my $first_line = $1;
$values{ operating_system_description } = $first_line;
$first_line =~ m{^(.*?)\s*(\d+)\s*\(.*?\)\s*$}
or runtime_error( "$release:1: Cannot parse line:", $first_line );
$values{ operating_system_name } = $1;
$bulk =~ m{^VERSION\s*=\s*(.*)\s*$}m
or runtime_error( "$release: There is no VERSION:", $bulk, "(eof)" );
$values{ operating_system_release } = $1;
if ( $bulk =~ m{^PATCHLEVEL\s*=\s*(.*)\s*$}m ) {
$values{ operating_system_release } .= ".$1";
}; # if
} elsif ( $release =~ m{debian_version} ) {
# Debian. The file debian_version contains just version number, nothing more:
# 4.0
my $name = "Debian";
$bulk =~ m{\A(.*)$}m
or runtime_error( "$release: Cannot find the first line:", $bulk, "(eof)" );
my $version = $1;
$values{ operating_system_name } = $name;
$values{ operating_system_release } = $version;
$values{ operating_system_codename } = "unknown";
$values{ operating_system_description } = sprintf( "%s %s", $name, $version );
}; # if
}; # if
}; # if
if ( not defined( $values{ operating_system_name } ) ) {
$values{ operating_system_name } = "GNU/Linux";
}; # if
} elsif ( $values{ kernel_name } eq "Darwin" ) {
my %codenames = (
10.4 => "Tiger",
10.5 => "Leopard",
10.6 => "Snow Leopard",
);
my $darwin;
my $get_os_info =
sub {
my ( $name ) = @_;
if ( not defined $darwin ) {
$darwin->{ operating_system } = "Darwin";
# sw_vers prints OS X* version to stdout:
# ProductName: OS X*
# ProductVersion: 10.4.11
# BuildVersion: 8S2167
# It does not print codename, so we code OS X* codenames here.
my $sw_vers = which( "sw_vers" ) || "/usr/bin/sw_vers";
my $output;
debug( "Executing $sw_vers..." );
execute( [ $sw_vers ], -stdout => \$output, -stderr => undef );
$output =~ m{^ProductName:\s*(.*)\s*$}m
or runtime_error( "There is no ProductName in sw_vers output:", $output, "(eof)" );
my $name = $1;
$output =~ m{^ProductVersion:\s*(.*)\s*$}m
or runtime_error( "There is no ProductVersion in sw_vers output:", $output, "(eof)" );
my $release = $1;
# Sometimes release reported as "10.4.11" (3 components), sometimes as "10.6".
# Handle both variants.
$release =~ m{^(\d+.\d+)(?:\.\d+)?(?=\s|$)}
or runtime_error( "Cannot parse OS X* version: $release" );
my $version = $1;
my $codename = ( $codenames{ $version } or "unknown" );
$darwin->{ operating_system_name } = $name;
$darwin->{ operating_system_release } = $release;
$darwin->{ operating_system_codename } = $codename;
$darwin->{ operating_system_description } = sprintf( "%s %s (%s)", $name, $release, $codename );
}; # if
return $darwin->{ $name };
}; # sub
$values{ operating_system } = sub { $get_os_info->( "operating_system" ); };
$values{ operating_system_name } = sub { $get_os_info->( "operating_system_name" ); };
$values{ operating_system_release } = sub { $get_os_info->( "operating_system_release" ); };
$values{ operating_system_codename } = sub { $get_os_info->( "operating_system_codename" ); };
$values{ operating_system_description } = sub { $get_os_info->( "operating_system_description" ); };
} elsif ( $values{ kernel_name } =~ m{\AWindows[ _]NT\z} ) {
$values{ operating_system } = "MS Windows";
# my @os_name = Win32::GetOSName();
# $values{ operating_system_release } = $os_name[ 0 ];
# $values{ operating_system_update } = $os_name[ 1 ];
} elsif ( $values{ kernel_name } =~ m{\ACYGWIN_NT-} ) {
$values{ operating_system } = "MS Windows";
} elsif ( $values{ kernel_name } =~ m{\AFreeBSD} ) {
$values{ operating_system } = "FreeBSD";
} elsif ( $values{ kernel_name } =~ m{\ANetBSD} ) {
$values{ operating_system } = "NetBSD";
} else {
die "Unsupported kernel_name (\"$values{ kernel_name }\") returned by POSIX::uname(); stopped";
}; # if
# host_name and domain_name
$values{ host_name } =
sub {
my $fqdn = value( "fqdn" );
$fqdn =~ m{\A([^.]*)(?:\.(.*))?\z};
my $host_name = $1;
if ( not defined( $host_name ) or $host_name eq "" ) {
die "Unexpected error: undefined or empty host name; stopped";
}; # if
return $host_name;
};
$values{ domain_name } =
sub {
my $fqdn = value( "fqdn" );
$fqdn =~ m{\A([^.]*)(?:\.(.*))?\z};
my $domain_name = $2;
if ( not defined( $domain_name ) or $domain_name eq "" ) {
die "Unexpected error: undefined or empty domain name; stopped";
}; # if
return $domain_name;
};
# Replace undefined values with "unknown".
foreach my $name ( @all ) {
if ( not defined( $values{ $name } ) ) {
$values{ $name } = "unknown";
}; # if
}; # foreach $name
# Export functions reporting properties.
foreach my $name ( @all ) {
no strict "refs";
*$name = sub { return value( $name ); };
}; # foreach $name
# This function returns base names.
sub base_names {
return @base;
}; # sub base_names
# This function returns all the names.
sub all_names {
return @all;
}; # sub all_names
# This function returns value by the specified name.
sub value($) {
my $name = shift( @_ );
if ( ref( $values{ $name } ) ) {
my $value = $values{ $name }->();
$values{ $name } = $value;
}; # if
return $values{ $name };
}; # sub value
return 1;
__END__
=pod
=head1 NAME
B<Uname.pm> -- A few subroutines to get system information usually provided by
C</bin/uname> and C<POSIX::uname()>.
=head1 SYNOPSIS
use Uname;
# Base property functions.
$kernel_name = Uname::kernel_name();
$fqdn = Uname::fqdn();
$kernel_release = Uname::kernel_release();
$kernel_version = Uname::kernel_version();
$machine = Uname::machine();
$processor = Uname::processor();
$hardware_platform = Uname::hardware_platform();
$operating_system = Uname::operating_system();
# Auxiliary property functions.
$host_name = Uname::host_name();
$domain_name = Uname::domain_name();
$os_name = Uname::operating_system_name();
$os_release = Uname::operating_system_release();
$os_codename = Uname::operating_system_codename();
$os_description = Uname::operating_system_description();
# Meta functions.
@base_names = Uname::base_names();
@all_names = Uname::all_names();
$kernel_name = Uname::value( "kernel_name" );
=head1 DESCRIPTION
B<Uname.pm> resembles functionality found in C<POSIX::uname()> function or in C<uname> program.
However, both C<POSIX::uname()> and C</bin/uname> have some disadvantages:
=over
=item *
C<uname> may be not available in some environments, for example, in Windows* OS
(C<uname> may be found in some third-party software packages, like MKS Toolkit or Cygwin, but it is
not a part of OS).
=item *
There are many different versions of C<uname>. For example, C<uname> on OS X* does not
recognize options C<-i>, C<-o>, and any long options.
=item *
Different versions of C<uname> may report the same property differently. For example,
C<uname> on Linux* OS reports machine as C<i686>, while C<uname> on OS X* reports the same machine as
C<x86>.
=item *
C<POSIX::uname()> returns list of values. I cannot recall what is the fourth element of the list.
=back
=head2 Base Functions
Base property functions provide the information as C<uname> program.
=over
=item B<kernel_name()>
Returns the kernel name, as reported by C<POSIX::uname()>.
=item B<fqdn()>
Returns the FQDN, fully qualified domain name. On some systems C<POSIX::uname()> reports short node
name (with no domain name), on others C<POSIX::uname()> reports full node name. This
function strive to return FQDN always (by refining C<POSIX::uname()> with
C<Net::Domain::hostfqdn()>).
=item B<kernel_release()>
Returns the kernel release string, as reported by C<POSIX::uname()>. Usually the string consists of
several numbers, separated by dots and dashes, but may also include some non-numeric substrings like
"smp".
=item B<kernel_version()>
Returns the kernel version string, as reported by C<POSIX::uname()>. It is B<not> several
dot-separated numbers but much longer string describing the kernel.
For example, on Linux* OS it includes build date.
If you look for something identifying the kernel, look at L<kernel_release>.
=item B<machine()>
Returns the machine hardware name, as reported by POSIX::uname(). Not reliable. Different OSes may
report the same machine hardware name differently. For example, Linux* OS reports C<i686>, while OS X*
reports C<x86> on the same machine.
=item B<processor()>
Returns the processor type. Not reliable. Usually the same as C<machine>.
=item B<hardware_platform()>
One of: C<i386> or C<x86_64>.
=item B<operating_system()>
One of: C<GNU/Linux>, C<OS X*>, or C<MS Windows>.
=back
=head2 Auxiliary Functions
Auxiliary functions extends base functions with information not reported by C<uname> program.
Auxiliary functions collect information from different sources. For example, on OS X*, they may
call C<sw_vers> program to find out OS release; on Linux* OS they may parse C</etc/redhat-release> file,
etc.
=over
=item B<host_name()>
Returns host name (FQDN with dropped domain part).
=item B<domain_name()>
Returns domain name (FQDN with dropped host part).
=item B<operating_system_name>
Name of operating system or name of Linux* OS distribution, like "Fedora" or
"Red Hat Enterprise Linux* OS Server".
=item B<operating_system_release>
Release (version) of operating system or Linux* OS distribution. Usually it is a series of
dot-separated numbers.
=item B<operating_system_codename>
Codename of operating system release or Linux* OS distribution. For example, Fedora 10 is "Cambridge"
while OS X* 10.4 is "Tiger".
=item B<operating_system_description>
Longer string. Usually it includes all the operating system properting mentioned above -- name,
release, codename in parentheses.
=back
=head2 Meta Functions
=over
=item B<base_names()>
This function returns the list of base property names.
=item B<all_names()>
This function returns the list of all property names.
=item B<value(> I<name> B<)>
This function returns the value of the property specified by I<name>.
=back
=head1 EXAMPLES
use Uname;
print( Uname::string(), "\n" );
foreach my $name ( Uname::all_names() ) {
print( "$name=\"" . Uname::value( $name ) . "\"\n" );
}; # foreach $name
=head1 SEE ALSO
L<POSIX::uname>, L<uname>.
=cut
# end of file #