############################################################################### ## ---------------------------------------------------------------------------- ## A threads-like parallelization module compatible with Perl 5.8. ## ############################################################################### use strict; use warnings; no warnings qw( threads recursion uninitialized once redefine ); package MCE::Child; our $VERSION = '1.889'; ## no critic (BuiltinFunctions::ProhibitStringyEval) ## no critic (Subroutines::ProhibitExplicitReturnUndef) ## no critic (Subroutines::ProhibitSubroutinePrototypes) ## no critic (TestingAndDebugging::ProhibitNoStrict) use MCE::Signal (); use MCE::Mutex (); use MCE::Channel (); use Time::HiRes 'sleep'; use overload ( q(==) => \&equal, q(!=) => sub { !equal(@_) }, fallback => 1 ); sub import { if (caller !~ /^MCE::/) { no strict 'refs'; no warnings 'redefine'; *{ caller().'::mce_child' } = \&mce_child; } return; } ## The POSIX module has many symbols. Try not loading it simply ## to have WNOHANG. The following covers most platforms. use constant { _WNOHANG => ( $INC{'POSIX.pm'} ) ? &POSIX::WNOHANG : ( $^O eq 'solaris' ) ? 64 : 1 }; my ( $_MNGD, $_DATA, $_DELY, $_LIST ) = ( {}, {}, {}, {} ); my $_is_MSWin32 = ( $^O eq 'MSWin32' ) ? 1 : 0; my $_tid = ( $INC{'threads.pm'} ) ? threads->tid() : 0; sub CLONE { $_tid = threads->tid(), &_clear() if $INC{'threads.pm'}; } sub _clear { %{ $_LIST } = (); } sub _max_workers { my ( $cpus ) = @_; if ( $cpus eq 'auto' ) { $cpus = MCE::Util::get_ncpu(); } elsif ( $cpus =~ /^([0-9.]+)%$/ ) { my ( $percent, $ncpu ) = ( $1 / 100, MCE::Util::get_ncpu() ); $cpus = $ncpu * $percent + 0.5; } $cpus = 1 if $cpus !~ /^[\d\.]+$/ || $cpus < 1; return int($cpus); } ############################################################################### ## ---------------------------------------------------------------------------- ## Init routine. ## ############################################################################### bless my $_SELF = { MGR_ID => "$$.$_tid", WRK_ID => $$ }, __PACKAGE__; sub init { shift if ( defined $_[0] && $_[0] eq __PACKAGE__ ); # -- options ---------------------------------------------------------- # max_workers child_timeout posix_exit on_start on_finish void_context # --------------------------------------------------------------------- my $pkg = "$$.$_tid.".( caller eq __PACKAGE__ ? caller(1) : caller ); my $mngd = $_MNGD->{$pkg} = ( ref $_[0] eq 'HASH' ) ? shift : { @_ }; @_ = (); $mngd->{MGR_ID} = "$$.$_tid", $mngd->{PKG} = $pkg, $mngd->{WRK_ID} = $$; &_force_reap($pkg), $_DATA->{$pkg}->clear() if ( exists $_LIST->{$pkg} ); if ( !exists $_LIST->{$pkg} ) { $MCE::_GMUTEX->lock() if ( $_tid && $MCE::_GMUTEX ); sleep 0.015 if $_tid; # Start the shared-manager process if not running. MCE::Shared->start() if $INC{'MCE/Shared.pm'}; my $chnl = MCE::Channel->new( impl => 'Mutex' ); $_LIST->{ $pkg } = MCE::Child::_ordhash->new(); $_DELY->{ $pkg } = MCE::Child::_delay->new( $chnl ); $_DATA->{ $pkg } = MCE::Child::_hash->new( $chnl ); $_DATA->{"$pkg:seed"} = int(rand() * 1e9); $_DATA->{"$pkg:id" } = 0; $MCE::_GMUTEX->unlock() if ( $_tid && $MCE::_GMUTEX ); } if ( !exists $mngd->{posix_exit} ) { $mngd->{posix_exit} = 1 if ( $^S || $_tid || $INC{'Mojo/IOLoop.pm'} || $INC{'Coro.pm'} || $INC{'LWP/UserAgent.pm'} || $INC{'stfl.pm'} || $INC{'Curses.pm'} || $INC{'CGI.pm'} || $INC{'FCGI.pm'} || $INC{'Tk.pm'} || $INC{'Wx.pm'} || $INC{'Win32/GUI.pm'} || $INC{'Gearman/Util.pm'} || $INC{'Gearman/XS.pm'} ); } if ( defined $mngd->{max_workers} ) { $mngd->{max_workers} = _max_workers($mngd->{max_workers}); } if ( $INC{'LWP/UserAgent.pm'} && !$INC{'Net/HTTP.pm'} ) { local $@; eval 'require Net::HTTP; require Net::HTTPS'; } require POSIX if ( $mngd->{on_finish} && !$INC{'POSIX.pm'} && !$_is_MSWin32 ); return; } ############################################################################### ## ---------------------------------------------------------------------------- ## 'new', 'mce_child', and 'create' for threads-like similarity. ## ############################################################################### ## 'new' and 'tid' are aliases for 'create' and 'pid' respectively. *new = \&create, *tid = \&pid; ## Use "goto" trick to avoid pad problems from 5.8.1 (fixed in 5.8.2) ## Tip found in threads::async. sub mce_child (&;@) { goto &create; } sub create { my $mngd = $_MNGD->{ "$$.$_tid.".caller() } || do { # construct mngd internally on first use unless defined init(); $_MNGD->{ "$$.$_tid.".caller() }; }; shift if ( $_[0] eq __PACKAGE__ ); # ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ my $self = bless ref $_[0] eq 'HASH' ? { %{ shift() } } : { }, __PACKAGE__; $self->{IGNORE} = 1 if $SIG{CHLD} eq 'IGNORE'; $self->{MGR_ID} = $mngd->{MGR_ID}, $self->{PKG} = $mngd->{PKG}; $self->{ident } = shift if ( !ref $_[0] && ref $_[1] eq 'CODE' ); my $func = shift; $func = caller().'::'.$func if ( !ref $func && length $func && index($func,':') < 0 ); if ( !defined $func ) { local $\; print {*STDERR} "code function is not specified or valid\n"; return undef; } my ( $list, $max_workers, $pkg ) = ( $_LIST->{ $mngd->{PKG} }, $mngd->{max_workers}, $mngd->{PKG} ); $_DATA->{"$pkg:id"} = 10000 if ( ( my $id = ++$_DATA->{"$pkg:id"} ) >= 2e9 ); { # Reap completed child processes. local ($SIG{CHLD}, $!, $?, $_); map { waitpid($_, 0); _reap_child($list->del($_), 0); (); } $_DATA->{$pkg}->reap_data; } if ( $max_workers || $self->{IGNORE} ) { # Wait for a slot if saturated. if ( $max_workers && $list->len() >= $max_workers ) { my $count = $list->len() - $max_workers + 1; _wait_one($pkg) for 1 .. $count; } } # ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ ~~~ $MCE::_GMUTEX->lock() if ( $_tid && $MCE::_GMUTEX ); my @args = @_; @_ = (); # To avoid (Scalars leaked: N) messages my ( $killed, $pid ); { local $SIG{TERM} = local $SIG{INT} = sub { $killed = $_[0] } if ( !$_is_MSWin32 && $] ge '5.010001' ); local $SIG{TTIN}, local $SIG{TTOU}, local $SIG{WINCH} if ( !$_is_MSWin32 ); $pid = fork(); if ( !defined $pid ) { # error local $\; print {*STDERR} "fork error: $!\n"; } elsif ( $pid ) { # parent $self->{WRK_ID} = $pid; $list->set($pid, $self); $mngd->{on_start}->($pid, $self->{ident}) if $mngd->{on_start}; } else { # child %{ $_LIST } = (), $_SELF = $self; local $SIG{TERM} = local $SIG{INT} = local $SIG{ABRT} = \&_trap, local $SIG{SEGV} = local $SIG{HUP} = \&_trap, local $SIG{QUIT} = \&_quit; local $SIG{CHLD}; MCE::Shared::init() if $INC{'MCE/Shared.pm'}; $_DATA->{ $_SELF->{PKG} }->set('S'.$$, '') unless $self->{IGNORE}; CORE::kill($killed, $$) if $killed; # Sets the seed of the base generator uniquely between workers. # The new seed is computed using the current seed and ID value. # One may set the seed at the application level for predictable # results. Ditto for Math::Prime::Util, Math::Random, and # Math::Random::MT::Auto. srand( abs($_DATA->{"$pkg:seed"} - ($id * 100000)) % 2147483560 ); if ( $INC{'Math/Prime/Util.pm'} ) { Math::Prime::Util::srand( abs($_DATA->{"$pkg:seed"} - ($id * 100000)) % 2147483560 ); } if ( $INC{'Math/Random.pm'} ) { my $cur_seed = Math::Random::random_get_seed(); my $new_seed = ($cur_seed < 1073741781) ? $cur_seed + ((abs($id) * 10000) % 1073741780) : $cur_seed - ((abs($id) * 10000) % 1073741780); Math::Random::random_set_seed($new_seed, $new_seed); } if ( $INC{'Math/Random/MT/Auto.pm'} ) { my $cur_seed = Math::Random::MT::Auto::get_seed()->[0]; my $new_seed = ($cur_seed < 1073741781) ? $cur_seed + ((abs($id) * 10000) % 1073741780) : $cur_seed - ((abs($id) * 10000) % 1073741780); Math::Random::MT::Auto::set_seed($new_seed); } _dispatch($mngd, $func, \@args); } } $MCE::_GMUTEX->unlock() if ( $_tid && $MCE::_GMUTEX ); CORE::kill($killed, $$) if $killed; return $pid ? $self : undef; } ############################################################################### ## ---------------------------------------------------------------------------- ## Public methods. ## ############################################################################### sub equal { return 0 unless ( ref $_[0] && ref $_[1] ); $_[0]->{WRK_ID} == $_[1]->{WRK_ID} ? 1 : 0; } sub error { _croak('Usage: $child->error()') unless ref( my $self = $_[0] ); $self->join() unless $self->{REAPED}; $self->{ERROR} || undef; } sub exit { shift if ( defined $_[0] && $_[0] eq __PACKAGE__ ); my ( $self ) = ( ref $_[0] ? shift : $_SELF ); my ( $pkg, $wrk_id ) = ( $self->{PKG}, $self->{WRK_ID} ); if ( $wrk_id == $$ && $self->{MGR_ID} eq "$$.$_tid" ) { MCE::Child->finish('MCE'); CORE::exit(@_); } elsif ( $wrk_id == $$ ) { alarm 0; my ( $exit_status, @res ) = @_; $? = $exit_status || 0; $_DATA->{$pkg}->set('R'.$wrk_id, @res ? \@res : ''); die "Child exited ($?)\n"; _exit($?); # not reached } return $self if $self->{REAPED}; if ( exists $_DATA->{$pkg} ) { sleep 0.015 until $_DATA->{$pkg}->exists('S'.$wrk_id); } else { sleep 0.030; } if ($_is_MSWin32) { CORE::kill('KILL', $wrk_id) if CORE::kill('ZERO', $wrk_id); } else { CORE::kill('QUIT', $wrk_id) if CORE::kill('ZERO', $wrk_id); } $self; } sub finish { _croak('Usage: MCE::Child->finish()') if ref($_[0]); shift if ( defined $_[0] && $_[0] eq __PACKAGE__ ); my $pkg = defined($_[0]) ? $_[0] : caller(); if ( $pkg eq 'MCE' ) { for my $key ( keys %{ $_LIST } ) { MCE::Child->finish($key); } } elsif ( exists $_LIST->{$pkg} ) { return if $MCE::Signal::KILLED; if ( exists $_DELY->{$pkg} ) { &_force_reap($pkg); delete($_DELY->{$pkg}), delete($_DATA->{"$pkg:seed"}), delete($_LIST->{$pkg}), delete($_DATA->{"$pkg:id"}), delete($_MNGD->{$pkg}), delete($_DATA->{ $pkg }); } } @_ = (); return; } sub is_joinable { _croak('Usage: $child->is_joinable()') unless ref( my $self = $_[0] ); my ( $wrk_id, $pkg ) = ( $self->{WRK_ID}, $self->{PKG} ); if ( $wrk_id == $$ ) { ''; } elsif ( $self->{MGR_ID} eq "$$.$_tid" ) { return '' if $self->{REAPED}; local $!; $_DATA->{$pkg}->reap_data; ( waitpid($wrk_id, _WNOHANG) == 0 ) ? '' : do { _reap_child($self, 0) unless $self->{REAPED}; 1; }; } else { # limitation for MCE::Child only; allowed for MCE::Hobo _croak('Error: $child->is_joinable() not called by managed process'); } } sub is_running { _croak('Usage: $child->is_running()') unless ref( my $self = $_[0] ); my ( $wrk_id, $pkg ) = ( $self->{WRK_ID}, $self->{PKG} ); if ( $wrk_id == $$ ) { 1; } elsif ( $self->{MGR_ID} eq "$$.$_tid" ) { return '' if $self->{REAPED}; local $!; $_DATA->{$pkg}->reap_data; ( waitpid($wrk_id, _WNOHANG) == 0 ) ? 1 : do { _reap_child($self, 0) unless $self->{REAPED}; ''; }; } else { # limitation for MCE::Child only; allowed for MCE::Hobo _croak('Error: $child->is_running() not called by managed process'); } } sub join { _croak('Usage: $child->join()') unless ref( my $self = $_[0] ); my ( $wrk_id, $pkg ) = ( $self->{WRK_ID}, $self->{PKG} ); if ( $self->{REAPED} ) { _croak('Child already joined') unless exists( $self->{RESULT} ); $_LIST->{$pkg}->del($wrk_id) if ( exists $_LIST->{$pkg} ); return ( defined wantarray ) ? wantarray ? @{ delete $self->{RESULT} } : delete( $self->{RESULT} )->[-1] : (); } if ( $wrk_id == $$ ) { _croak('Cannot join self'); } elsif ( $self->{MGR_ID} eq "$$.$_tid" ) { # remove from list after reaping local $SIG{CHLD}; _reap_child($self, 1); $_LIST->{$pkg}->del($wrk_id); } else { # limitation for MCE::Child only; allowed for MCE::Hobo _croak('Error: $child->join() not called by managed process'); } return unless ( exists $self->{RESULT} ); ( defined wantarray ) ? wantarray ? @{ delete $self->{RESULT} } : delete( $self->{RESULT} )->[-1] : (); } sub kill { _croak('Usage: $child->kill()') unless ref( my $self = $_[0] ); my ( $wrk_id, $pkg, $signal ) = ( $self->{WRK_ID}, $self->{PKG}, $_[1] ); if ( $wrk_id == $$ ) { CORE::kill($signal || 'INT', $$); return $self; } if ( $self->{MGR_ID} eq "$$.$_tid" ) { return $self if $self->{REAPED}; if ( exists $_DATA->{$pkg} ) { sleep 0.015 until $_DATA->{$pkg}->exists('S'.$wrk_id); } else { sleep 0.030; } } CORE::kill($signal || 'INT', $wrk_id) if CORE::kill('ZERO', $wrk_id); $self; } sub list { _croak('Usage: MCE::Child->list()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); ( exists $_LIST->{$pkg} ) ? $_LIST->{$pkg}->vals() : (); } sub list_pids { _croak('Usage: MCE::Child->list_pids()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); local $_; ( exists $_LIST->{$pkg} ) ? map { $_->pid } $_LIST->{$pkg}->vals() : (); } sub list_joinable { _croak('Usage: MCE::Child->list_joinable()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); return () unless ( my $list = $_LIST->{$pkg} ); local ($!, $?, $_); $_DATA->{$pkg}->reap_data; map { ( waitpid($_->{WRK_ID}, _WNOHANG) == 0 ) ? () : do { _reap_child($_, 0) unless $_->{REAPED}; $_; }; } $list->vals(); } sub list_running { _croak('Usage: MCE::Child->list_running()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); return () unless ( my $list = $_LIST->{$pkg} ); local ($!, $?, $_); $_DATA->{$pkg}->reap_data; map { ( waitpid($_->{WRK_ID}, _WNOHANG) == 0 ) ? $_ : do { _reap_child($_, 0) unless $_->{REAPED}; (); }; } $list->vals(); } sub max_workers { _croak('Usage: MCE::Child->max_workers()') if ref($_[0]); my $mngd = $_MNGD->{ "$$.$_tid.".caller() } || do { # construct mngd internally on first use unless defined init(); $_MNGD->{ "$$.$_tid.".caller() }; }; shift if ( $_[0] eq __PACKAGE__ ); $mngd->{max_workers} = _max_workers(shift) if @_; $mngd->{max_workers}; } sub pending { _croak('Usage: MCE::Child->pending()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); ( exists $_LIST->{$pkg} ) ? $_LIST->{$pkg}->len() : 0; } sub pid { ref($_[0]) ? $_[0]->{WRK_ID} : $_SELF->{WRK_ID}; } sub result { _croak('Usage: $child->result()') unless ref( my $self = $_[0] ); return $self->join() unless $self->{REAPED}; _croak('Child already joined') unless exists( $self->{RESULT} ); wantarray ? @{ delete $self->{RESULT} } : delete( $self->{RESULT} )->[-1]; } sub self { ref($_[0]) ? $_[0] : $_SELF; } sub wait_all { _croak('Usage: MCE::Child->wait_all()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); return wantarray ? () : 0 if ( !exists $_LIST->{$pkg} || !$_LIST->{$pkg}->len() ); local $_; ( wantarray ) ? map { $_->join(); $_ } $_LIST->{$pkg}->vals() : map { $_->join(); () } $_LIST->{$pkg}->vals(); } *waitall = \&wait_all; # compatibility sub wait_one { _croak('Usage: MCE::Child->wait_one()') if ref($_[0]); my $pkg = "$$.$_tid.".caller(); return undef if ( !exists $_LIST->{$pkg} || !$_LIST->{$pkg}->len() ); _wait_one($pkg); } *waitone = \&wait_one; # compatibility sub yield { _croak('Usage: MCE::Child->yield()') if ref($_[0]); shift if ( defined $_[0] && $_[0] eq __PACKAGE__ ); my $pkg = $_SELF->{PKG} || do { my $mngd = $_MNGD->{ "$$.$_tid.".caller() } || do { # construct mngd internally on first use unless defined init(); $_MNGD->{ "$$.$_tid.".caller() }; }; $mngd->{PKG}; }; return unless $_DELY->{$pkg}; my $seconds = $_DELY->{$pkg}->seconds(@_); MCE::Util::_sleep( $seconds ); } ############################################################################### ## ---------------------------------------------------------------------------- ## Private methods. ## ############################################################################### sub _croak { if ( $INC{'MCE.pm'} ) { goto &MCE::_croak; } else { $SIG{__DIE__} = \&MCE::Signal::_die_handler; $SIG{__WARN__} = \&MCE::Signal::_warn_handler; $\ = undef; goto &Carp::croak; } } sub _dispatch { my ( $mngd, $func, $args ) = @_; $mngd->{WRK_ID} = $_SELF->{WRK_ID} = $$, $? = 0; $ENV{PERL_MCE_IPC} = 'win32' if $_is_MSWin32; { local $!; (*STDERR)->autoflush(1) if defined( fileno *STDERR ); (*STDOUT)->autoflush(1) if defined( fileno *STDOUT ); } # Run task. my $child_timeout = ( exists $_SELF->{child_timeout} ) ? $_SELF->{child_timeout} : $mngd->{child_timeout}; my $void_context = ( exists $_SELF->{void_context} ) ? $_SELF->{void_context} : $mngd->{void_context}; my @res; my $timed_out = 0; local $SIG{'ALRM'} = sub { alarm 0; $timed_out = 1; $SIG{__WARN__} = sub {}; die "Child timed out\n"; }; if ( $void_context || $_SELF->{IGNORE} ) { no strict 'refs'; eval { alarm($child_timeout || 0); $func->(@{ $args }) }; } else { no strict 'refs'; @res = eval { alarm($child_timeout || 0); $func->(@{ $args }) }; } alarm 0; $@ = "Child timed out" if $timed_out; if ( $@ ) { _exit($?) if ( $@ =~ /^Child exited \(\S+\)$/ ); my $err = $@; $? = 1; $err =~ s/, <__ANONIO__> line \d+//; if ( ! $_SELF->{IGNORE} ) { $_DATA->{ $_SELF->{PKG} }->set('S'.$$, $err), $_DATA->{ $_SELF->{PKG} }->set('R'.$$, ''); } if ( !$timed_out && !$mngd->{on_finish} && !$INC{'MCE/Simple.pm'} ) { use bytes; warn "Child $$ terminated abnormally: reason $err\n"; } } else { shift(@res) if ref($res[0]) =~ /^MCE::(?:Barrier|Semaphore)::_guard/s; $_DATA->{ $_SELF->{PKG} }->set('R'.$$, @res ? \@res : '') if ( ! $_SELF->{IGNORE} ); } _exit($?); } sub _exit { my ( $exit_status ) = @_; # Check for nested workers not yet joined. MCE::Child->finish('MCE') if ( !$_SELF->{SIGNALED} && keys %{ $_LIST } ); # Exit child process. $SIG{__DIE__} = sub {} unless $_tid; $SIG{__WARN__} = sub {}; threads->exit($exit_status) if ( $INC{'threads.pm'} && $_is_MSWin32 ); my $posix_exit = ( exists $_SELF->{posix_exit} ) ? $_SELF->{posix_exit} : $_MNGD->{ $_SELF->{PKG} }{posix_exit}; if ( $posix_exit && !$_SELF->{SIGNALED} && !$_is_MSWin32 ) { eval { MCE::Mutex::Channel::_destroy() }; POSIX::_exit($exit_status) if $INC{'POSIX.pm'}; CORE::kill('KILL', $$); } CORE::exit($exit_status); } sub _force_reap { my ( $count, $pkg ) = ( 0, @_ ); return unless ( exists $_LIST->{$pkg} && $_LIST->{$pkg}->len() ); for my $child ( $_LIST->{$pkg}->vals() ) { next if $child->{IGNORE}; if ( $child->is_running() ) { sleep(0.015), CORE::kill('KILL', $child->pid()) if CORE::kill('ZERO', $child->pid()); $count++; } } $_LIST->{$pkg}->clear(); warn "Finished with active child processes [$pkg] ($count)\n" if ( $count && !$_is_MSWin32 ); return; } sub _quit { return MCE::Signal::defer($_[0]) if $MCE::Signal::IPC; alarm 0; my ( $name ) = @_; $_SELF->{SIGNALED} = 1, $name =~ s/^SIG//; $SIG{$name} = sub {}, CORE::kill($name, -$$) if ( exists $SIG{$name} ); if ( ! $_SELF->{IGNORE} ) { my ( $pkg, $wrk_id ) = ( $_SELF->{PKG}, $_SELF->{WRK_ID} ); $_DATA->{$pkg}->set('R'.$wrk_id, ''); } _exit(0); } sub _reap_child { my ( $child, $wait_flag ) = @_; return unless $child; local @_ = $_DATA->{ $child->{PKG} }->get( $child->{WRK_ID}, $wait_flag ); ( $child->{ERROR}, $child->{RESULT}, $child->{REAPED} ) = ( pop || '', length $_[0] ? pop : [], 1 ); return if $child->{IGNORE}; my ( $exit, $err ) = ( $? || 0, $child->{ERROR} ); my ( $code, $sig ) = ( $exit >> 8, $exit & 0x7f ); if ( $code > 100 && !$err ) { $code = 2, $sig = 1, $err = 'Child received SIGHUP' if $code == 101; $code = 2, $sig = 2, $err = 'Child received SIGINT' if $code == 102; $code = 2, $sig = 6, $err = 'Child received SIGABRT' if $code == 106; $code = 2, $sig = 11, $err = 'Child received SIGSEGV' if $code == 111; $code = 2, $sig = 15, $err = 'Child received SIGTERM' if $code == 115; $child->{ERROR} = $err; } if ( my $on_finish = $_MNGD->{ $child->{PKG} }{on_finish} ) { $on_finish->( $child->{WRK_ID}, $code, $child->{ident}, $sig, $err, @{ $child->{RESULT} } ); } return; } sub _trap { return MCE::Signal::defer($_[0]) if $MCE::Signal::IPC; alarm 0; my ( $exit_status, $name ) = ( 2, @_ ); $_SELF->{SIGNALED} = 1, $name =~ s/^SIG//; $SIG{$name} = sub {}, CORE::kill($name, -$$) if ( exists $SIG{$name} ); if ( $name eq 'HUP' ) { $exit_status = 101 } elsif ( $name eq 'INT' ) { $exit_status = 102 } elsif ( $name eq 'ABRT' ) { $exit_status = 106 } elsif ( $name eq 'SEGV' ) { $exit_status = 111 } elsif ( $name eq 'TERM' ) { $exit_status = 115 } if ( ! $_SELF->{IGNORE} ) { my ( $pkg, $wrk_id ) = ( $_SELF->{PKG}, $_SELF->{WRK_ID} ); $_DATA->{$pkg}->set('R'.$wrk_id, ''); } _exit($exit_status); } sub _wait_one { my ( $pkg ) = @_; my ( $list, $self, $wrk_id ) = ( $_LIST->{$pkg} ); local $!; while () { $_DATA->{$pkg}->reap_data; for my $child ( $list->vals() ) { $wrk_id = $child->{WRK_ID}; return $list->del($wrk_id) if $child->{REAPED}; $self = $list->del($wrk_id), last if waitpid($wrk_id, _WNOHANG); } last if $self; sleep 0.030; } _reap_child($self, 0); $self; } ############################################################################### ## ---------------------------------------------------------------------------- ## Delay implementation suited for MCE::Child. ## ############################################################################### package # hide from rpm MCE::Child::_delay; sub new { my ( $class, $chnl, $delay ) = @_; if ( !defined $delay ) { $delay = ($^O =~ /mswin|mingw|msys|cygwin/i) ? 0.015 : 0.008; } $chnl->send(undef); bless [ $delay, $chnl ], $class; } sub seconds { my ( $self, $how_long ) = @_; my $delay = defined($how_long) ? $how_long : $self->[0]; my $lapse = $self->[1]->recv(); my $time = MCE::Util::_time(); if ( !$delay || !defined $lapse ) { $lapse = $time; } elsif ( $lapse + $delay - $time < 0 ) { $lapse += int( abs($time - $lapse) / $delay + 0.5 ) * $delay; } $self->[1]->send( $lapse += $delay ); return $lapse - $time; } ############################################################################### ## ---------------------------------------------------------------------------- ## Hash and ordhash implementations suited for MCE::Child. ## ############################################################################### package # hide from rpm MCE::Child::_hash; use Time::HiRes 'sleep'; use constant { _WNOHANG => ( $INC{'POSIX.pm'} ) ? &POSIX::WNOHANG : ( $^O eq 'solaris' ) ? 64 : 1 }; sub new { my ( $class, $chnl ) = @_; bless [ {}, $chnl ], shift; } sub clear { my ( $self ) = @_; 1 while ( $self->[1]->recv2_nb() ); %{ $self->[0] } = (); } sub exists { my ( $self, $key ) = @_; while ( my $data = $self->[1]->recv2_nb() ) { $self->[0]{ $data->[0] } = $data->[1]; } CORE::exists $self->[0]{ $key }; } sub get { my ( $self, $wrk_id, $wait_flag ) = @_; if ( !CORE::exists $self->[0]{ 'R'.$wrk_id } ) { while ( my $data = $self->[1]->recv2_nb() ) { $self->[0]{ $data->[0] } = $data->[1]; } } if ( $wait_flag ) { local $!; ( CORE::exists $self->[0]{ 'R'.$wrk_id } ) ? waitpid($wrk_id, 0) : do { while () { my $data = $self->[1]->recv2_nb(); if ( !defined $data ) { last if waitpid($wrk_id, _WNOHANG); sleep(0.0009), next; } $self->[0]{ $data->[0] } = $data->[1]; waitpid($wrk_id, 0), last if $data->[0] eq 'R'.$wrk_id; } if ( !CORE::exists $self->[0]{ 'R'.$wrk_id } ) { while ( my $data = $self->[1]->recv2_nb() ) { $self->[0]{ $data->[0] } = $data->[1]; } } }; } my $result = delete $self->[0]{ 'R'.$wrk_id }; my $error = delete $self->[0]{ 'S'.$wrk_id }; $result = '' unless ( defined $result ); $error = '' unless ( defined $error ); return ( $result, $error ); } sub reap_data { my ( $self ) = @_; if (wantarray) { my @ret; while ( my $data = $self->[1]->recv2_nb() ) { push @ret, substr($data->[0], 1) if substr($data->[0], 0, 1) eq 'R'; $self->[0]{ $data->[0] } = $data->[1]; } return @ret; } while ( my $data = $self->[1]->recv2_nb() ) { $self->[0]{ $data->[0] } = $data->[1]; } return; } sub set { $_[0]->[1]->send2([ $_[1], $_[2] ]); } package # hide from rpm MCE::Child::_ordhash; sub new { bless [ {}, [], {}, 0 ], shift; } # data, keys, indx, gcnt sub exists { CORE::exists $_[0]->[0]{ $_[1] }; } sub get { $_[0]->[0]{ $_[1] }; } sub len { scalar keys %{ $_[0]->[0] }; } sub clear { my ( $self ) = @_; %{ $self->[0] } = @{ $self->[1] } = %{ $self->[2] } = (), $self->[3] = 0; return; } sub del { my ( $self, $key ) = @_; return undef unless defined( my $off = delete $self->[2]{$key} ); # tombstone $self->[1][$off] = undef; # GC keys and refresh index if ( ++$self->[3] > @{ $self->[1] } * 0.667 ) { my ( $keys, $indx ) = ( $self->[1], $self->[2] ); my $i; $i = $self->[3] = 0; for my $k ( @{ $keys } ) { $keys->[$i] = $k, $indx->{$k} = $i++ if defined($k); } splice @{ $keys }, $i; } delete $self->[0]{$key}; } sub set { my ( $self, $key ) = @_; $self->[0]{$key} = $_[2], return 1 if exists($self->[0]{$key}); $self->[2]{$key} = @{ $self->[1] }; push @{ $self->[1] }, $key; $self->[0]{$key} = $_[2]; return 1; } sub vals { my ( $self ) = @_; $self->[3] ? @{ $self->[0] }{ grep defined($_), @{ $self->[1] } } : @{ $self->[0] }{ @{ $self->[1] } }; } 1; __END__ ############################################################################### ## ---------------------------------------------------------------------------- ## Module usage. ## ############################################################################### =head1 NAME MCE::Child - A threads-like parallelization module compatible with Perl 5.8 =head1 VERSION This document describes MCE::Child version 1.889 =head1 SYNOPSIS use MCE::Child; MCE::Child->init( max_workers => 'auto', # default undef, unlimited # Specify a percentage. MCE::Child 1.876+. max_workers => '25%', # 4 on HW with 16 lcores max_workers => '50%', # 8 on HW with 16 lcores child_timeout => 20, # default undef, no timeout posix_exit => 1, # default undef, CORE::exit void_context => 1, # default undef on_start => sub { my ( $pid, $ident ) = @_; ... }, on_finish => sub { my ( $pid, $exit, $ident, $signal, $error, @ret ) = @_; ... } ); MCE::Child->create( sub { print "Hello from child\n" } )->join(); sub parallel { my ($arg1) = @_; print "Hello again, $arg1\n" if defined($arg1); print "Hello again, $_\n"; # same thing } MCE::Child->create( \¶llel, $_ ) for 1 .. 3; my @procs = MCE::Child->list(); my @pids = MCE::Child->list_pids(); my @running = MCE::Child->list_running(); my @joinable = MCE::Child->list_joinable(); my @count = MCE::Child->pending(); # Joining is orderly, e.g. child1 is joined first, child2, child3. $_->join() for @procs; # (or) $_->join() for @joinable; # Joining occurs immediately as child processes complete execution. 1 while MCE::Child->wait_one(); my $child = mce_child { foreach (@files) { ... } }; $child->join(); if ( my $err = $child->error() ) { warn "Child error: $err\n"; } # Get a child's object $child = MCE::Child->self(); # Get a child's ID $pid = MCE::Child->pid(); # $$ $pid = $child->pid(); $pid = MCE::Child->tid(); # tid is an alias for pid $pid = $child->tid(); # Test child objects if ( $child1 == $child2 ) { ... } # Give other workers a chance to run MCE::Child->yield(); MCE::Child->yield(0.05); # Return context, wantarray aware my ($value1, $value2) = $child->join(); my $value = $child->join(); # Check child's state if ( $child->is_running() ) { sleep 1; } if ( $child->is_joinable() ) { $child->join(); } # Send a signal to a child $child->kill('SIGUSR1'); # Exit a child MCE::Child->exit(0); MCE::Child->exit(0, @ret); =head1 DESCRIPTION L is a fork of L for compatibility with Perl 5.8. A child is a migratory worker inside the machine that carries the asynchronous gene. Child processes are equipped with C-like capability for running code asynchronously. Unlike threads, each child is a unique process to the underlying OS. The IPC is handled via C, which runs on all the major platforms including Cygwin and Strawberry Perl. C may be used as a standalone or together with C including running alongside C. use MCE::Child; use MCE::Shared; # synopsis: head -20 file.txt | perl script.pl my $ifh = MCE::Shared->handle( "<", \*STDIN ); # shared my $ofh = MCE::Shared->handle( ">", \*STDOUT ); my $ary = MCE::Shared->array(); sub parallel_task { my ( $id ) = @_; while ( <$ifh> ) { printf {$ofh} "[ %4d ] %s", $., $_; # $ary->[ $. - 1 ] = "[ ID $id ] read line $.\n" ); # dereferencing $ary->set( $. - 1, "[ ID $id ] read line $.\n" ); # faster via OO } } my $child1 = MCE::Child->new( "parallel_task", 1 ); my $child2 = MCE::Child->new( \¶llel_task, 2 ); my $child3 = MCE::Child->new( sub { parallel_task(3) } ); $_->join for MCE::Child->list(); # ditto: MCE::Child->wait_all(); # search array (total one round-trip via IPC) my @vals = $ary->vals( "val =~ / ID 2 /" ); print {*STDERR} join("", @vals); =head1 API DOCUMENTATION =over 3 =item $child = MCE::Child->create( FUNCTION, ARGS ) =item $child = MCE::Child->new( FUNCTION, ARGS ) This will create a new child process that will begin execution with function as the entry point, and optionally ARGS for list of parameters. It will return the corresponding MCE::Child object, or undef if child creation failed. I may either be the name of a function, an anonymous subroutine, or a code ref. my $child = MCE::Child->create( "func_name", ... ); # or my $child = MCE::Child->create( sub { ... }, ... ); # or my $child = MCE::Child->create( \&func, ... ); =item $child = MCE::Child->create( { options }, FUNCTION, ARGS ) =item $child = MCE::Child->create( IDENT, FUNCTION, ARGS ) Options, excluding C, may be specified globally via the C function. Otherwise, C, C, C, and C may be set uniquely. The C option is used by callback functions C and C for identifying the started and finished child process respectively. my $child1 = MCE::Child->create( { posix_exit => 1 }, sub { ... } ); $child1->join; my $child2 = MCE::Child->create( { child_timeout => 3 }, sub { sleep 1 for ( 1 .. 9 ); } ); $child2->join; if ( $child2->error() eq "Child timed out\n" ) { ... } The C method is an alias for C. =item mce_child { BLOCK } ARGS; =item mce_child { BLOCK }; C runs the block asynchronously similarly to C<< MCE::Child->create() >>. It returns the child object, or undef if child creation failed. my $child = mce_child { foreach (@files) { ... } }; $child->join(); if ( my $err = $child->error() ) { warn("Child error: $err\n"); } =item $child->join() This will wait for the corresponding child process to complete its execution. In non-voided context, C will return the value(s) of the entry point function. The context (void, scalar or list) for the return value(s) for C is determined at the time of joining and mostly C aware. my $child1 = MCE::Child->create( sub { my @res = qw(foo bar baz); return (@res); }); my @res1 = $child1->join(); # ( foo, bar, baz ) my $res1 = $child1->join(); # baz my $child2 = MCE::Child->create( sub { return 'foo'; }); my @res2 = $child2->join(); # ( foo ) my $res2 = $child2->join(); # foo =item $child1->equal( $child2 ) Tests if two child objects are the same child or not. Child comparison is based on process IDs. This is overloaded to the more natural forms. if ( $child1 == $child2 ) { print("Child objects are the same\n"); } # or if ( $child1 != $child2 ) { print("Child objects differ\n"); } =item $child->error() Child processes are executed in an C context. This method will return C if the child terminates I. Otherwise, it returns the value of C<$@> associated with the child's execution status in its C context. =item $child->exit() This sends C<'SIGQUIT'> to the child process, notifying the child to exit. It returns the child object to allow for method chaining. It is important to join later if not immediately to not leave a zombie or defunct process. $child->exit()->join(); ... $child->join(); # later =item MCE::Child->exit( 0 ) =item MCE::Child->exit( 0, @ret ) A child can exit at any time by calling C<< MCE::Child->exit() >>. Otherwise, the behavior is the same as C when called from the main process. The child process may optionally return data, to be sent via IPC. =item MCE::Child->finish() This class method is called automatically by C, but may be called explicitly. An error is emitted via croak if there are active child processes not yet joined. MCE::Child->create( 'task1', $_ ) for 1 .. 4; $_->join for MCE::Child->list(); MCE::Child->create( 'task2', $_ ) for 1 .. 4; $_->join for MCE::Child->list(); MCE::Child->create( 'task3', $_ ) for 1 .. 4; $_->join for MCE::Child->list(); MCE::Child->finish(); =item MCE::Child->init( options ) The init function accepts a list of MCE::Child options. MCE::Child->init( max_workers => 'auto', # default undef, unlimited # Specify a percentage. MCE::Child 1.876+. max_workers => '25%', # 4 on HW with 16 lcores max_workers => '50%', # 8 on HW with 16 lcores child_timeout => 20, # default undef, no timeout posix_exit => 1, # default undef, CORE::exit void_context => 1, # default undef on_start => sub { my ( $pid, $ident ) = @_; ... }, on_finish => sub { my ( $pid, $exit, $ident, $signal, $error, @ret ) = @_; ... } ); # Identification given as an option or the 1st argument. for my $key ( 'aa' .. 'zz' ) { MCE::Child->create( { ident => $key }, sub { ... } ); MCE::Child->create( $key, sub { ... } ); } MCE::Child->wait_all; Set C if you want to limit the number of workers by waiting automatically for an available slot. Specify a percentage or C to obtain the number of logical cores via C. Set C, in number of seconds, if you want the child process to terminate after some time. The default is C<0> for no timeout. Set C to avoid all END and destructor processing. Constructing MCE::Child inside a thread implies 1 or if present CGI, FCGI, Coro, Curses, Gearman::Util, Gearman::XS, LWP::UserAgent, Mojo::IOLoop, STFL, Tk, Wx, or Win32::GUI. Set C to create the child process in void context for the return value. Otherwise, the return context is wantarray-aware for C and C and determined when retrieving the data. The callback options C and C are called in the parent process after starting the worker and later when terminated. The arguments for the subroutines were inspired by L. The parameters for C are the following: - pid of the child process - identification (ident option or 1st arg to create) The parameters for C are the following: - pid of the child process - program exit code - identification (ident option or 1st arg to create) - exit signal id - error message from eval inside MCE::Child - returned data =item $child->is_running() Returns true if a child is still running. =item $child->is_joinable() Returns true if the child has finished running and not yet joined. =item $child->kill( 'SIG...' ) Sends the specified signal to the child. Returns the child object to allow for method chaining. As with C, it is important to join eventually if not immediately to not leave a zombie or defunct process. $child->kill('SIG...')->join(); The following is a parallel demonstration comparing C against C and C on a Fedora 23 VM. Joining begins after all workers have been notified to quit. use Time::HiRes qw(time); use Redis; use Redis::Fast; use MCE::Child; use MCE::Shared; my $redis = Redis->new(); my $rfast = Redis::Fast->new(); my $array = MCE::Shared->array(); sub parallel_redis { my ($_redis) = @_; my ($count, $quit, $len) = (0, 0); # instead, use a flag to exit loop $SIG{'QUIT'} = sub { $quit = 1 }; while () { $len = $_redis->rpush('list', $count++); last if $quit; } $count; } sub parallel_array { my ($count, $quit, $len) = (0, 0); # do not exit from inside handler $SIG{'QUIT'} = sub { $quit = 1 }; while () { $len = $array->push($count++); last if $quit; } $count; } sub benchmark_this { my ($desc, $num_procs, $timeout, $code, @args) = @_; my ($start, $total) = (time(), 0); MCE::Child->new($code, @args) for 1..$num_procs; sleep $timeout; # joining is not immediate; ok $_->kill('QUIT') for MCE::Child->list(); # joining later; ok $total += $_->join() for MCE::Child->list(); printf "$desc <> duration: %0.03f secs, count: $total\n", time() - $start; sleep 0.2; } benchmark_this('Redis ', 8, 5.0, \¶llel_redis, $redis); benchmark_this('Redis::Fast', 8, 5.0, \¶llel_redis, $rfast); benchmark_this('MCE::Shared', 8, 5.0, \¶llel_array); =item MCE::Child->list() Returns a list of all child objects not yet joined. @procs = MCE::Child->list(); =item MCE::Child->list_pids() Returns a list of all child pids not yet joined (available since 1.849). @pids = MCE::Child->list_pids(); $SIG{INT} = $SIG{HUP} = $SIG{TERM} = sub { # Signal workers all at once CORE::kill('KILL', MCE::Child->list_pids()); exec('reset'); }; =item MCE::Child->list_running() Returns a list of all child objects that are still running. @procs = MCE::Child->list_running(); =item MCE::Child->list_joinable() Returns a list of all child objects that have completed running. Thus, ready to be joined without blocking. @procs = MCE::Child->list_joinable(); =item MCE::Child->max_workers([ N ]) Getter and setter for max_workers. Specify a number or 'auto' to acquire the total number of cores via MCE::Util::get_ncpu. Specify a false value to set back to no limit. =item MCE::Child->pending() Returns a count of all child objects not yet joined. $count = MCE::Child->pending(); =item $child->result() Returns the result obtained by C, C, or C. If the process has not yet exited, waits for the corresponding child to complete its execution. use MCE::Child; use Time::HiRes qw(sleep); sub task { my ($id) = @_; sleep $id * 0.333; return $id; } MCE::Child->create('task', $_) for ( reverse 1 .. 3 ); # 1 while MCE::Child->wait_one(); while ( my $child = MCE::Child->wait_one() ) { my $err = $child->error() || 'no error'; my $res = $child->result(); my $pid = $child->pid(); print "[$pid] $err : $res\n"; } Like C described above, the context (void, scalar or list) for the return value(s) is determined at the time C is called and mostly C aware. my $child1 = MCE::Child->create( sub { my @res = qw(foo bar baz); return (@res); }); my @res1 = $child1->result(); # ( foo, bar, baz ) my $res1 = $child1->result(); # baz my $child2 = MCE::Child->create( sub { return 'foo'; }); my @res2 = $child2->result(); # ( foo ) my $res2 = $child2->result(); # foo =item MCE::Child->self() Class method that allows a child to obtain it's own I object. =item $child->pid() =item $child->tid() Returns the ID of the child. pid: $$ process id tid: $$ alias for pid =item MCE::Child->pid() =item MCE::Child->tid() Class methods that allows a child to obtain its own ID. pid: $$ process id tid: $$ alias for pid =item MCE::Child->wait_one() =item MCE::Child->waitone() =item MCE::Child->wait_all() =item MCE::Child->waitall() Meaningful for the manager process only, waits for one or all child processes to complete execution. Afterwards, returns the corresponding child objects. If a child doesn't exist, returns the C value or an empty list for C and C respectively. The C and C methods are aliases for compatibility with C. use MCE::Child; use Time::HiRes qw(sleep); sub task { my $id = shift; sleep $id * 0.333; return $id; } MCE::Child->create('task', $_) for ( reverse 1 .. 3 ); # join, traditional use case $_->join() for MCE::Child->list(); # wait_one, simplistic use case 1 while MCE::Child->wait_one(); # wait_one while ( my $child = MCE::Child->wait_one() ) { my $err = $child->error() || 'no error'; my $res = $child->result(); my $pid = $child->pid(); print "[$pid] $err : $res\n"; } # wait_all my @procs = MCE::Child->wait_all(); for ( @procs ) { my $err = $_->error() || 'no error'; my $res = $_->result(); my $pid = $_->pid(); print "[$pid] $err : $res\n"; } =item MCE::Child->yield( [ floating_seconds ] ) Give other workers a chance to run, optionally for given time. Yield behaves similarly to MCE's interval option. It throttles workers from running too fast. A demonstration is provided in the next section for fetching URLs in parallel. The default C is 0.008 and 0.015 on UNIX and Windows, respectively. Pass 0 if simply wanting to give other workers a chance to run. # total run time: 1.00 second MCE::Child->create( sub { MCE::Child->yield(0.25) } ) for 1 .. 4; MCE::Child->wait_all(); =back =head1 THREADS-like DETACH CAPABILITY Threads-like detach capability was added starting with the 1.867 release. A threads example is shown first followed by the MCE::Child example. All one needs to do is set the CHLD signal handler to IGNORE. Unfortunately, this works on UNIX platforms only. The child process restores the CHLD handler to default, so is able to deeply spin workers and reap if desired. use threads; for ( 1 .. 8 ) { async { # do something }->detach; } use MCE::Child; # Have the OS reap workers automatically when exiting. # The on_finish option is ignored if specified (no-op). # Ensure not inside a thread on UNIX platforms. $SIG{CHLD} = 'IGNORE'; for ( 1 .. 8 ) { mce_child { # do something }; } # Optionally, wait for any remaining workers before leaving. # This is necessary if workers are consuming shared objects, # constructed via MCE::Shared. MCE::Child->wait_all; The following is another way and works on Windows. Here, the on_finish handler works as usual. use MCE::Child; MCE::Child->init( on_finish = sub { ... }, ); for ( 1 .. 8 ) { $_->join for MCE::Child->list_joinable; mce_child { # do something }; } MCE::Child->wait_all; =head1 PARALLEL::FORKMANAGER-like DEMONSTRATION MCE::Child behaves similarly to threads for the most part. It also provides L-like capabilities. The C example is shown first followed by a version using C. =over 3 =item Parallel::ForkManager use strict; use warnings; use Parallel::ForkManager; use Time::HiRes 'time'; my $start = time; my $pm = Parallel::ForkManager->new(10); $pm->set_waitpid_blocking_sleep(0); $pm->run_on_finish( sub { my ($pid, $exit_code, $ident, $exit_signal, $core_dumped, $resp) = @_; print "child $pid completed: $ident => ", $resp->[0], "\n"; }); DATA_LOOP: foreach my $data ( 1..2000 ) { # forks and returns the pid for the child my $pid = $pm->start($data) and next DATA_LOOP; my $ret = [ $data * 2 ]; $pm->finish(0, $ret); } $pm->wait_all_children; printf STDERR "duration: %0.03f seconds\n", time - $start; =item MCE::Child use strict; use warnings; use MCE::Child 1.843; use Time::HiRes 'time'; my $start = time; MCE::Child->init( max_workers => 10, on_finish => sub { my ($pid, $exit_code, $ident, $exit_signal, $error, $resp) = @_; print "child $pid completed: $ident => ", $resp->[0], "\n"; } ); foreach my $data ( 1..2000 ) { MCE::Child->create( $data, sub { [ $data * 2 ]; }); } MCE::Child->wait_all; printf STDERR "duration: %0.03f seconds\n", time - $start; =item Time to spin 2,000 workers and obtain results (in seconds). Results were obtained on a Macbook Pro (2.6 GHz ~ 3.6 GHz with Turbo Boost). Parallel::ForkManager 2.02 uses Moo. Therefore, I ran again with Moo loaded at the top of the script. MCE::Hobo uses MCE::Shared to retrieve data during reaping. MCE::Child uses MCE::Channel, no shared-manager. Version Cygwin Windows Linux macOS FreeBSD MCE::Child 1.843 19.099s 17.091s 0.965s 1.534s 1.229s MCE::Hobo 1.843 20.514s 19.594s 1.246s 1.629s 1.613s P::FM 1.20 19.703s 19.235s 0.875s 1.445s 1.346s MCE::Child 1.843 20.426s 18.417s 1.116s 1.632s 1.338s Moo loaded MCE::Hobo 1.843 21.809s 20.810s 1.407s 1.759s 1.722s Moo loaded P::FM 2.02 21.668s 25.927s 1.882s 2.612s 2.483s Moo used =item Set posix_exit to avoid all END and destructor processing. This is helpful for reducing overhead when workers exit. Ditto if using a Perl module not parallel safe. The option is ignored on Windows C<$^O eq 'MSWin32'>. MCE::Child->init( posix_exit => 1, ... ); MCE::Hobo->init( posix_exit => 1, ... ); Version Cygwin Windows Linux macOS FreeBSD MCE::Child 1.843 19.815s ignored 0.824s 1.284s 1.245s Moo loaded MCE::Hobo 1.843 21.029s ignored 0.953s 1.335s 1.439s Moo loaded =back =head1 PARALLEL HTTP GET DEMONSTRATION USING ANYEVENT This demonstration constructs two queues, two handles, starts the shared-manager process if needed, and spawns four workers. For this demonstration, am chunking 64 URLs per job. In reality, one may run with 200 workers and chunk 300 URLs on a 24-way box. # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ # perl demo.pl -- all output # perl demo.pl >/dev/null -- mngr/child output # perl demo.pl 2>/dev/null -- show results only # # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ use strict; use warnings; use AnyEvent; use AnyEvent::HTTP; use Time::HiRes qw( time ); use MCE::Child; use MCE::Shared; # Construct two queues, input and return. my $que = MCE::Shared->queue(); my $ret = MCE::Shared->queue(); # Construct shared handles for serializing output from many workers # writing simultaneously. This prevents garbled output. mce_open my $OUT, ">>", \*STDOUT or die "open error: $!"; mce_open my $ERR, ">>", \*STDERR or die "open error: $!"; # Spawn workers early for minimum memory consumption. MCE::Child->create({ posix_exit => 1 }, 'task', $_) for 1 .. 4; # Obtain or generate input data for workers to process. my ( $count, @urls ) = ( 0 ); push @urls, map { "http://127.0.0.$_/" } 1..254; push @urls, map { "http://192.168.0.$_/" } 1..254; # 508 URLs total while ( @urls ) { my @chunk = splice(@urls, 0, 64); $que->enqueue( { ID => ++$count, INPUT => \@chunk } ); } # So that workers leave the loop after consuming the queue. $que->end(); # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ # Loop for the manager process. The manager may do other work if # need be and periodically check $ret->pending() not shown here. # # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ my $start = time; printf {$ERR} "Mngr - entering loop\n"; while ( $count ) { my ( $result, $failed ) = $ret->dequeue( 2 ); # Remove ID from result, so not treated as a URL item. printf {$ERR} "Mngr - received job %s\n", delete $result->{ID}; # Display the URL and the size captured. foreach my $url ( keys %{ $result } ) { printf {$OUT} "%s: %d\n", $url, length($result->{$url}) if $result->{$url}; # url has content } # Display URLs could not reach. if ( @{ $failed } ) { foreach my $url ( @{ $failed } ) { print {$OUT} "Failed: $url\n"; } } # Decrement the count. $count--; } MCE::Child->wait_all(); printf {$ERR} "Mngr - exiting loop\n\n"; printf {$ERR} "Duration: %0.3f seconds\n\n", time - $start; exit; # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ # Child processes enqueue two items ( $result and $failed ) per each # job for the manager process. Likewise, the manager process dequeues # two items above. Optionally, child processes may include the ID in # the result. # # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ sub task { my ( $id ) = @_; printf {$ERR} "Child $id entering loop\n"; while ( my $job = $que->dequeue() ) { my ( $result, $failed ) = ( { ID => $job->{ID} }, [ ] ); # Walk URLs, provide a hash and array refs for data. printf {$ERR} "Child $id running job $job->{ID}\n"; walk( $job, $result, $failed ); # Send results to the manager process. $ret->enqueue( $result, $failed ); } printf {$ERR} "Child $id exiting loop\n"; } sub walk { my ( $job, $result, $failed ) = @_; # Yielding is critical when running an event loop in parallel. # Not doing so means that the app may reach contention points # with the firewall and likely impose unnecessary hardship at # the OS level. The idea here is not to have multiple workers # initiate HTTP requests to a batch of URLs at the same time. # Yielding behaves similarly like scatter to have the child # process run solo for a fraction of time. MCE::Child->yield( 0.03 ); my $cv = AnyEvent->condvar(); # Populate the hash ref for the URLs it could reach. # Do not mix AnyEvent timeout with child timeout. # Therefore, choose event timeout when available. foreach my $url ( @{ $job->{INPUT} } ) { $cv->begin(); http_get $url, timeout => 2, sub { my ( $data, $headers ) = @_; $result->{$url} = $data; $cv->end(); }; } $cv->recv(); # Populate the array ref for URLs it could not reach. foreach my $url ( @{ $job->{INPUT} } ) { push @{ $failed }, $url unless (exists $result->{ $url }); } return; } __END__ $ perl demo.pl Child 1 entering loop Child 2 entering loop Child 3 entering loop Mngr - entering loop Child 2 running job 2 Child 3 running job 3 Child 1 running job 1 Child 4 entering loop Child 4 running job 4 Child 2 running job 5 Mngr - received job 2 Child 3 running job 6 Mngr - received job 3 Child 1 running job 7 Mngr - received job 1 Child 4 running job 8 Mngr - received job 4 http://192.168.0.1/: 3729 Child 2 exiting loop Mngr - received job 5 Child 3 exiting loop Mngr - received job 6 Child 1 exiting loop Mngr - received job 7 Child 4 exiting loop Mngr - received job 8 Mngr - exiting loop Duration: 4.131 seconds =head1 CROSS-PLATFORM TEMPLATE FOR BINARY EXECUTABLE Making an executable is possible with the L module. On the Windows platform, threads, threads::shared, and exiting via threads are necessary for the binary to exit successfully. # https://metacpan.org/pod/PAR::Packer # https://metacpan.org/pod/pp # # pp -o demo.exe demo.pl # ./demo.exe use strict; use warnings; use if $^O eq "MSWin32", "threads"; use if $^O eq "MSWin32", "threads::shared"; # Include minimum dependencies for MCE::Child. # Add other modules required by your application here. use Storable (); use Time::HiRes (); # use IO::FDPass (); # optional: for condvar, handle, queue # use Sereal (); # optional: for faster serialization use MCE::Child; use MCE::Shared; # For PAR to work on the Windows platform, one must include manually # any shared modules used by the application. # use MCE::Shared::Array; # if using MCE::Shared->array # use MCE::Shared::Cache; # if using MCE::Shared->cache # use MCE::Shared::Condvar; # if using MCE::Shared->condvar # use MCE::Shared::Handle; # if using MCE::Shared->handle, mce_open # use MCE::Shared::Hash; # if using MCE::Shared->hash # use MCE::Shared::Minidb; # if using MCE::Shared->minidb # use MCE::Shared::Ordhash; # if using MCE::Shared->ordhash # use MCE::Shared::Queue; # if using MCE::Shared->queue # use MCE::Shared::Scalar; # if using MCE::Shared->scalar # Et cetera. Only load modules needed for your application. use MCE::Shared::Sequence; # if using MCE::Shared->sequence my $seq = MCE::Shared->sequence( 1, 9 ); sub task { my ( $id ) = @_; while ( defined ( my $num = $seq->next() ) ) { print "$id: $num\n"; sleep 1; } } sub main { MCE::Child->new( \&task, $_ ) for 1 .. 3; MCE::Child->wait_all(); } # Main must run inside a thread on the Windows platform or workers # will fail duing exiting, causing the exe to crash. The reason is # that PAR or a dependency isn't multi-process safe. ( $^O eq "MSWin32" ) ? threads->create(\&main)->join() : main(); threads->exit(0) if $INC{"threads.pm"}; =head1 LIMITATION MCE::Child emits an error when C, C, and C isn't called by the managed process, where the child was spawned. This is a limitation in MCE::Child only due to not involving a shared-manager process for IPC. This use-case is not typical. =head1 CREDITS The inspiration for C comes from wanting C-like behavior for processes compatible with Perl 5.8. Both can run side-by-side including safe-use by MCE workers. Likewise, the documentation resembles C. The inspiration for C and C comes from the C module. =head1 SEE ALSO =over 3 =item * L =item * L =item * L =item * L =item * L =item * L =item * L =item * L =item * L =item * L =back =head1 INDEX L, L, L =head1 AUTHOR Mario E. Roy, Smarioeroy AT gmail DOT comE> =cut