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Man Pages
MCE::Shared(3) User Contributed Perl Documentation MCE::Shared(3)

MCE::Shared - MCE extension for sharing data supporting threads and processes

This document describes MCE::Shared version 1.876

 # OO construction.

 use MCE::Shared;

 my $ar = MCE::Shared->array( @list );
 my $ca = MCE::Shared->cache( max_keys => 500, max_age => 60 );
 my $cv = MCE::Shared->condvar( 0 );
 my $fh = MCE::Shared->handle( '>>', \*STDOUT ) or die "$!";
 my $ha = MCE::Shared->hash( @pairs );
 my $oh = MCE::Shared->ordhash( @pairs );
 my $db = MCE::Shared->minidb();
 my $qu = MCE::Shared->queue( await => 1, fast => 0 );
 my $va = MCE::Shared->scalar( $value );
 my $se = MCE::Shared->sequence( $begin, $end, $step, $fmt );
 my $ob = MCE::Shared->share( $blessed_object );

 # Mutex locking is supported for all shared objects since 1.841.
 # Previously only shared C<condvar>s allowed locking.

 $ar->lock;
 $ar->unlock;
 ...
 $ob->lock;
 $ob->unlock;

 # The Perl-like mce_open function is available since 1.002.

 mce_open my $fh, ">>", "/foo/bar.log" or die "open error: $!";

 # Tie construction. The module API option is available since 1.825.

 use v5.10;
 use MCE::Flow;
 use MCE::Shared;

 my %args  = ( max_keys => 500, max_age => 60 );
 my @pairs = ( foo => 'bar', woo => 'baz' );
 my @list  = ( 'a' .. 'z' );

 tie my $va1, 'MCE::Shared', { module => 'MCE::Shared::Scalar' }, 0;
 tie my @ar1, 'MCE::Shared', { module => 'MCE::Shared::Array' }, @list;
 tie my %ca1, 'MCE::Shared', { module => 'MCE::Shared::Cache' }, %args;
 tie my %ha1, 'MCE::Shared', { module => 'MCE::Shared::Hash' }, @pairs;
 tie my %oh1, 'MCE::Shared', { module => 'MCE::Shared::Ordhash' }, @pairs;
 tie my %oh2, 'MCE::Shared', { module => 'Hash::Ordered' }, @pairs;
 tie my %oh3, 'MCE::Shared', { module => 'Tie::IxHash' }, @pairs;
 tie my $cy1, 'MCE::Shared', { module => 'Tie::Cycle' }, [ 1 .. 8 ];
 tie my $va2, 'MCE::Shared', { module => 'Tie::StdScalar' }, 'hello';
 tie my @ar3, 'MCE::Shared', { module => 'Tie::StdArray' }, @list;
 tie my %ha2, 'MCE::Shared', { module => 'Tie::StdHash' }, @pairs;
 tie my %ha3, 'MCE::Shared', { module => 'Tie::ExtraHash' }, @pairs;

 tie my $cnt, 'MCE::Shared', 0; # default MCE::Shared::Scalar
 tie my @foo, 'MCE::Shared';    # default MCE::Shared::Array
 tie my %bar, 'MCE::Shared';    # default MCE::Shared::Hash

 tie my @ary, 'MCE::Shared', qw( a list of values );
 tie my %ha,  'MCE::Shared', key1 => 'val1', key2 => 'val2';
 tie my %ca,  'MCE::Shared', { max_keys => 500, max_age => 60 };
 tie my %oh,  'MCE::Shared', { ordered => 1 }, key1 => 'value';

 # Mutex locking is supported for all shared objects since 1.841.

 tied($va1)->lock;
 tied($va1)->unlock;
 ...
 tied(%bar)->lock;
 tied(%bar)->unlock;

 # Demonstration.

 my $mutex = MCE::Mutex->new;

 mce_flow {
    max_workers => 4
 },
 sub {
    my ( $mce ) = @_;
    my ( $pid, $wid ) = ( MCE->pid, MCE->wid );

    # Locking is necessary when multiple workers update the same
    # element. The reason is that it may involve 2 trips to the
    # shared-manager process: fetch and store in this case.

    $mutex->enter( sub { $cnt += 1 } );

    # Otherwise, locking is optional for unique elements.

    $foo[ $wid - 1 ] = $pid;
    $bar{ $pid }     = $wid;

    # From 1.841 onwards, all shared objects include mutex locking
    # to not need to construct MCE::Mutex separately.

    tied($va1)->lock;
    $va1 += 1;
    tied($va1)->unlock;

    return;
 };

 say "scalar : $cnt";
 say "scalar : $va1";
 say " array : $_" for (@foo);
 say "  hash : $_ => $bar{$_}" for (sort keys %bar);

 __END__

 # Output

 scalar : 4
 scalar : 4
  array : 37847
  array : 37848
  array : 37849
  array : 37850
   hash : 37847 => 1
   hash : 37848 => 2
   hash : 37849 => 3
   hash : 37850 => 4

This module provides data sharing capabilities for MCE supporting threads and processes. MCE::Hobo provides threads-like parallelization for running code asynchronously.

MCE::Shared enables extra functionality on systems with IO::FDPass installed. Without it, MCE::Shared is unable to send file descriptors to the shared-manager process. The use applies to Condvar, Queue, and Handle (mce_open). IO::FDpass isn't used for anything else.

 use MCE::Shared;

 # One may want to start the shared-manager early.

 MCE::Shared->start();

 # Typically, the shared-manager is started automatically when
 # constructing a shared object.

 my $ca = MCE::Shared->cache( max_keys => 500 );

 # IO::FDPass is necessary for constructing a shared condvar or queue
 # while the manager is running in order to send file descriptors
 # associated with the object.

 # Workers block using a socket handle for ->wait and ->timedwait.

 my $cv = MCE::Shared->condvar();

 # Workers block using a socket handle for ->dequeue and ->await.

 my $q1 = MCE::Shared->queue();
 my $q2 = MCE::Shared->queue( await => 1 );

For platforms where IO::FDPass isn't possible (e.g. Cygwin), construct "condvar" and "queue" before other classes. The shared-manager process will be delayed until sharing other classes (e.g. Array, Hash) or starting explicitly.

 use MCE::Shared;

 my $has_IO_FDPass = $INC{'IO/FDPass.pm'} ? 1 : 0;

 my $cv  = MCE::Shared->condvar( 0 );
 my $que = MCE::Shared->queue( fast => 1 );

 MCE::Shared->start() unless $has_IO_FDPass;

 my $ha = MCE::Shared->hash();  # started implicitly

Note that MCE starts the shared-manager, prior to spawning workers, if not yet started. Ditto for MCE::Hobo.

Regarding mce_open, "IO::FDPass" is needed for constructing a shared-handle from a non-shared handle not yet available inside the shared-manager process. The workaround is to have the non-shared handle made before the shared-manager is started. Passing a file by reference is fine for the three STD* handles.

 # The shared-manager knows of \*STDIN, \*STDOUT, \*STDERR.

 mce_open my $shared_in,  "<",  \*STDIN;   # ok
 mce_open my $shared_out, ">>", \*STDOUT;  # ok
 mce_open my $shared_err, ">>", \*STDERR;  # ok
 mce_open my $shared_fh1, "<",  "/path/to/sequence.fasta";  # ok
 mce_open my $shared_fh2, ">>", "/path/to/results.log";     # ok

 mce_open my $shared_fh, ">>", \*NON_SHARED_FH;  # requires IO::FDPass

The IO::FDPass module is known to work reliably on most platforms. Install 1.1 or later to rid of limitations described above.

 perl -MIO::FDPass -le "print 'Cheers! Perl has IO::FDPass.'"

MCE::Shared->array MCE::Shared::Array
MCE::Shared->cache MCE::Shared::Cache
MCE::Shared->condvar MCE::Shared::Condvar
MCE::Shared->handle MCE::Shared::Handle
MCE::Shared->hash MCE::Shared::Hash
MCE::Shared->minidb MCE::Shared::Minidb
MCE::Shared->ordhash MCE::Shared::Ordhash
MCE::Shared->queue MCE::Shared::Queue
MCE::Shared->scalar MCE::Shared::Scalar
MCE::Shared->sequence MCE::Shared::Sequence

Below, synopsis for sharing classes included with MCE::Shared.

 use MCE::Shared;

 # short form

 $ar = MCE::Shared->array( @list );
 $ca = MCE::Shared->cache( max_keys => 500, max_age => 60 );
 $cv = MCE::Shared->condvar( 0 );
 $fh = MCE::Shared->handle( ">>", \*STDOUT ); # see mce_open below
 $ha = MCE::Shared->hash( @pairs );
 $db = MCE::Shared->minidb();
 $oh = MCE::Shared->ordhash( @pairs );
 $qu = MCE::Shared->queue( await => 1, fast => 0 );
 $va = MCE::Shared->scalar( $value );
 $se = MCE::Shared->sequence( $begin, $end, $step, $fmt );

 mce_open my $fh, ">>", \*STDOUT or die "open error: $!";

 # long form

 $ar = MCE::Shared->share( { module => 'MCE::Shared::Array'    }, ... );
 $ca = MCE::Shared->share( { module => 'MCE::Shared::Cache'    }, ... );
 $cv = MCE::Shared->share( { module => 'MCE::Shared::Condvar'  }, ... );
 $fh = MCE::Shared->share( { module => 'MCE::Shared::Handle'   }, ... );
 $ha = MCE::Shared->share( { module => 'MCE::Shared::Hash'     }, ... );
 $db = MCE::Shared->share( { module => 'MCE::Shared::Minidb'   }, ... );
 $oh = MCE::Shared->share( { module => 'MCE::Shared::Ordhash'  }, ... );
 $qu = MCE::Shared->share( { module => 'MCE::Shared::Queue'    }, ... );
 $va = MCE::Shared->share( { module => 'MCE::Shared::Scalar'   }, ... );
 $se = MCE::Shared->share( { module => 'MCE::Shared::Sequence' }, ... );

The restriction for sharing classes not included with MCE::Shared is that the object must not have file-handles nor code-blocks.

 $oh = MCE::Shared->share( { module => 'Hash::Ordered' }, ... );
open ( filehandle, expr )
open ( filehandle, mode, expr )
open ( filehandle, mode, reference )

In version 1.002 and later, constructs a new object by opening the file whose filename is given by "expr", and associates it with "filehandle". When omitting error checking at the application level, MCE::Shared emits a message and stop if open fails.

See MCE::Shared::Handle for chunk IO demonstrations.

 {
   use MCE::Shared::Handle;

   # "non-shared" or "local construction" for use by a single process
   MCE::Shared::Handle->open( my $fh, "<", "file.log" ) or die "$!";
   MCE::Shared::Handle::open  my $fh, "<", "file.log"   or die "$!";

   # mce_open is an alias for MCE::Shared::Handle::open
   mce_open my $fh, "<", "file.log" or die "$!";
 }

 {
   use MCE::Shared;

   # construction for "sharing" with other threads and processes
   MCE::Shared->open( my $fh, "<", "file.log" ) or die "$!";
   MCE::Shared::open  my $fh, "<", "file.log"   or die "$!";

   # mce_open is an alias for MCE::Shared::open
   mce_open my $fh, "<", "file.log" or die "$!";
 }
mce_open ( filehandle, expr )
mce_open ( filehandle, mode, expr )
mce_open ( filehandle, mode, reference )

Native Perl-like syntax to open a shared-file for reading:

 use MCE::Shared;

 # mce_open is exported by MCE::Shared or MCE::Shared::Handle.
 # It creates a shared file handle with MCE::Shared present
 # or a non-shared handle otherwise.

 mce_open my $fh, "< input.txt"     or die "open error: $!";
 mce_open my $fh, "<", "input.txt"  or die "open error: $!";
 mce_open my $fh, "<", \*STDIN      or die "open error: $!";

and for writing:

 mce_open my $fh, "> output.txt"    or die "open error: $!";
 mce_open my $fh, ">", "output.txt" or die "open error: $!";
 mce_open my $fh, ">", \*STDOUT     or die "open error: $!";
num_sequence

"num_sequence" is an alias for "sequence".

The following is a demonstration for a shared tied-hash variable. Before venturing into the actual code, notice the dump function making a call to "export" explicitly for objects of type "MCE::Shared::Object". This is necessary in order to retrieve the data from the shared-manager process.

The "export" method is described later under the Common API section.

 use MCE::Shared;

 sub _dump {
    require Data::Dumper unless $INC{'Data/Dumper.pm'};
    no warnings 'once';

    local $Data::Dumper::Varname  = 'VAR';
    local $Data::Dumper::Deepcopy = 1;
    local $Data::Dumper::Indent   = 1;
    local $Data::Dumper::Purity   = 1;
    local $Data::Dumper::Sortkeys = 0;
    local $Data::Dumper::Terse    = 0;

    ( ref $_[0] eq 'MCE::Shared::Object' )
       ? print Data::Dumper::Dumper( $_[0]->export ) . "\n"
       : print Data::Dumper::Dumper( $_[0] ) . "\n";
 }

 tie my %abc, 'MCE::Shared';

 my @parents = qw( a b c );
 my @children = qw( 1 2 3 4 );

 for my $parent ( @parents ) {
    for my $child ( @children ) {
       $abc{ $parent }{ $child } = 1;
    }
 }

 _dump( tied( %abc ) );

 __END__

 # Output

 $VAR1 = bless( {
   'c' => bless( {
     '1' => '1',
     '4' => '1',
     '3' => '1',
     '2' => '1'
   }, 'MCE::Shared::Hash' ),
   'a' => bless( {
     '1' => '1',
     '4' => '1',
     '3' => '1',
     '2' => '1'
   }, 'MCE::Shared::Hash' ),
   'b' => bless( {
     '1' => '1',
     '4' => '1',
     '3' => '1',
     '2' => '1'
   }, 'MCE::Shared::Hash' )
 }, 'MCE::Shared::Hash' );

Dereferencing provides hash-like behavior for "hash" and "ordhash". Array-like behavior is allowed for "array", not shown below.

 use MCE::Shared;
 use Data::Dumper;

 my $abc = MCE::Shared->hash;

 my @parents = qw( a b c );
 my @children = qw( 1 2 3 4 );

 for my $parent ( @parents ) {
    for my $child ( @children ) {
       $abc->{ $parent }{ $child } = 1;
    }
 }

 print Dumper( $abc->export({ unbless => 1 }) ), "\n";

Each level in a deeply structure requires a separate trip to the shared-manager process. The included "MCE::Shared::Minidb" module provides optimized methods for working with hash of hashes "HoH" and hash of arrays "HoA".

 use MCE::Shared;
 use Data::Dumper;

 my $abc = MCE::Shared->minidb;

 my @parents = qw( a b c );
 my @children = qw( 1 2 3 4 );

 for my $parent ( @parents ) {
    for my $child ( @children ) {
       $abc->hset($parent, $child, 1);
    }
 }

 print Dumper( $abc->export ), "\n";

For further reading, see MCE::Shared::Minidb.

MCE::Shared->share

This class method transfers the blessed-object to the shared-manager process and returns a "MCE::Shared::Object" containing the "SHARED_ID". Starting with the 1.827 release, the "module" option sends parameters to the shared-manager, where the object is then constructed. This is useful for classes involving XS code or a file handle.

 use MCE::Shared;

 {
   use Math::BigFloat try => 'GMP';
   use Math::BigInt   try => 'GMP';

   my $bf  = MCE::Shared->share({ module => 'Math::BigFloat' }, 0);
   my $bi  = MCE::Shared->share({ module => 'Math::BigInt'   }, 0);
   my $y   = 1e9;

   $bf->badd($y);  # addition (add $y to shared BigFloat object)
   $bi->badd($y);  # addition (add $y to shared BigInt object)
 }

 {
   use Bio::Seq;
   use Bio::SeqIO;

   my $seq_io = MCE::Shared->share({ module => 'Bio::SeqIO' },
      -file    => ">/path/to/fasta/file.fa",
      -format  => 'Fasta',
      -verbose => -1,
   );

   my $seq_obj = Bio::Seq->new(
      -display_id => "name", -desc => "desc", -seq => "seq",
      -alphabet   => "dna"
   );

   $seq_io->write_seq($seq_obj);  # write to shared SeqIO handle
 }

 {
   my $oh1 = MCE::Shared->share({ module => 'MCE::Shared::Ordhash' });
   my $oh2 = MCE::Shared->ordhash();  # same thing

   $oh1->assign( @pairs );
   $oh2->assign( @pairs );
 }

 {
   my ($ho_shared, $ho_nonshared);

   $ho_shared = MCE::Shared->share({ module => 'Hash::Ordered' });
   $ho_shared->push( @pairs );

   $ho_nonshared = $ho_shared->export();   # back to non-shared
   $ho_nonshared = $ho_shared->destroy();  # including shared destruction
 }

The following provides long and short forms for constructing a shared array, hash, or scalar object.

 use MCE::Shared;

 my $a1 = MCE::Shared->share( { module => 'MCE::Shared::Array' }, @list );
 my $a2 = MCE::Shared->share( [ @list ] );
 my $a3 = MCE::Shared->array( @list );

 my $h1 = MCE::Shared->share( { module => 'MCE::Shared::Hash' }, @pairs );
 my $h2 = MCE::Shared->share( { @pairs } );
 my $h3 = MCE::Shared->hash( @pairs );

 my $s1 = MCE::Shared->share( { module => 'MCE::Shared::Scalar' }, 20 );
 my $s2 = MCE::Shared->share( \do{ my $o = 20 } );
 my $s3 = MCE::Shared->scalar( 20 );

When the "module" option is given, one may optionally specify the constructor function via the "new" option. This is necessary for the CDB_File module, which provides two different objects. One is created by new (default), and accessed by insert and finish. The other is created by TIEHASH, and accessed by FETCH.

 use MCE::Hobo;
 use MCE::Shared;

 # populate CDB file
 my $cdb = MCE::Shared->share({ module => 'CDB_File' }, 't.cdb', "t.cdb.$$")
    or die "$!\n";

 $cdb->insert( $_ => $_ ) for ('aa'..'zz');
 $cdb->finish;

 # use CDB file
 my $cdb1 = tie my %hash, 'MCE::Shared', { module => 'CDB_File' }, 't.cdb';

 # same thing, without involving TIE and extra hash variable
 my $cdb2 = MCE::Shared->share(
    { module => 'CDB_File', new => 'TIEHASH' }, 't.cdb'
 );

 print $hash{'aa'}, "\n";
 print $cdb1->FETCH('bb'), "\n";
 print $cdb2->FETCH('cc'), "\n";

 # rewind may be omitted on first use for parallel iteration
 $cdb2->rewind;

 for ( 1 .. 3 ) {
    mce_async {
       while ( my ($k,$v) = $cdb2->next ) {
          print "[$$] $k => $v\n";
       }
    };
 }

 MCE::Hobo->waitall;

Construting a shared DBM object is possible starting with the 1.827 release. Supported modules are AnyDBM_File, BerkeleyDB, CDB_File, DB_File, GDBM_File, NDBM_File, ODBM_File, SDBM_File, SQLite_File, Tie::Array::DBD, and Tie::Hash::DBD. The list includes Tokyo Cabinet <http://fallabs.com/tokyocabinet/> and Kyoto Cabinet <http://fallabs.com/kyotocabinet/>. Also, see forked version by Altice Labs <https://github.com/alticelabs/kyoto>. It contains an updated "kyotocabinet" folder that builds successfully with recent compilers.

Freeze-thaw during "STORE"-"FETCH" (for complex data) is handled automatically using Serial 3.015+ (if available) or Storable. Below, are constructions for sharing various DBM modules. The construction for "CDB_File" is given in the prior section.

AnyDBM_File

 BEGIN { @AnyDBM_File::ISA = qw( DB_File GDBM_File NDBM_File ODBM_File ); }

 use MCE::Shared;
 use Fcntl;
 use AnyDBM_File;

 tie my %h1, 'MCE::Shared', { module => 'AnyDBM_File' },
    'foo_a', O_CREAT|O_RDWR or die "open error: $!";
BerkeleyDB

 use MCE::Shared;
 use BerkeleyDB;

 tie my %h1, 'MCE::Shared', { module => 'BerkeleyDB::Hash' },
    -Filename => 'foo_a', -Flags => DB_CREATE
       or die "open error: $!";

 tie my %h2, 'MCE::Shared', { module => 'BerkeleyDB::Btree' },
    -Filename => 'foo_b', -Flags => DB_CREATE
       or die "open error: $!";

 tie my @a1, 'MCE::Shared', { module => 'BerkeleyDB::Queue' },
    -Filename => 'foo_c', -Flags => DB_CREATE
       or die "open error: $!";

 tie my @a2, 'MCE::Shared', { module => 'BerkeleyDB::Recno' },
    -Filename => 'foo_d', -Flags => DB_CREATE -Len => 20
       or die "open error: $!";
DB_File

 use MCE::Shared;
 use Fcntl;
 use DB_File;

 # Use pre-defined references ( $DB_HASH, $DB_BTREE, $DB_RECNO ).

 tie my %h1, 'MCE::Shared', { module => 'DB_File' },
    'foo_a', O_CREAT|O_RDWR, 0640, $DB_HASH or die "open error: $!";

 tie my %h2, 'MCE::Shared', { module => 'DB_File' },
    'foo_b', O_CREAT|O_RDWR, 0640, $DB_BTREE or die "open error: $!";

 tie my @a1, 'MCE::Shared', { module => 'DB_File' },
    'foo_c', O_CREAT|O_RDWR, 0640, $DB_RECNO or die "open error: $!";

 # Changing defaults - see DB_File for valid options.

 my $opt_h = DB_File::HASHINFO->new();
 my $opt_b = DB_File::BTREEINFO->new();
 my $opt_r = DB_File::RECNOINFO->new();

 $opt_h->{'cachesize'} = 12345;

 tie my %h3, 'MCE::Shared', { module => 'DB_File' },
    'foo_d', O_CREAT|O_RDWR, 0640, $opt_h or die "open error: $!";
KyotoCabinet
TokyoCabinet

 use MCE::Shared;
 use KyotoCabinet;
 use TokyoCabinet;

 # file extension denotes hash database

 tie my %h1, 'MCE::Shared', { module => 'KyotoCabinet::DB' }, 'foo.kch',
    KyotoCabinet::DB::OWRITER | KyotoCabinet::DB::OCREATE
       or die "open error: $!";

 tie my %h2, 'MCE::Shared', { module => 'TokyoCabinet::HDB' }, 'foo.tch',
    TokyoCabinet::HDB::OWRITER | TokyoCabinet::HDB::OCREAT
       or die "open error: $!";

 # file extension denotes tree database

 tie my %h3, 'MCE::Shared', { module => 'KyotoCabinet::DB' }, 'foo.kct',
    KyotoCabinet::DB::OWRITER | KyotoCabinet::DB::OCREATE
       or die "open error: $!";

 tie my %h4, 'MCE::Shared', { module => 'TokyoCabinet::BDB' }, 'foo.tcb',
    TokyoCabinet::BDB::OWRITER | TokyoCabinet::BDB::OCREAT
       or die "open error: $!";

 # on-memory hash database

 tie my %h5, 'MCE::Shared', { module => 'KyotoCabinet::DB' }, '*';
 tie my %h6, 'MCE::Shared', { module => 'TokyoCabinet::ADB' }, '*';

 # on-memory tree database

 tie my %h7, 'MCE::Shared', { module => 'KyotoCabinet::DB' }, '%#pccap=256m';
 tie my %h8, 'MCE::Shared', { module => 'TokyoCabinet::ADB' }, '+';
Tie::Array::DBD
Tie::Hash::DBD

 use MCE::Shared;
 use Tie::Array::DBD;
 use Tie::Hash::DBD;

 # A valid string is required for the DSN argument, not a DBI handle.
 # Do not specify the 'str' option for Tie::(Array|Hash)::DBD.
 # Instead, see encoder-decoder methods described under Common API.

 use DBD::SQLite;

 tie my @a1, 'MCE::Shared', { module => 'Tie::Array::DBD' },
    'dbi:SQLite:dbname=foo_a.db', {
       tbl => 't_tie_analysis',
       key => 'h_key',
       fld => 'h_value'
    };

 tie my %h1, 'MCE::Shared', { module => 'Tie::Hash::DBD' },
    'dbi:SQLite:dbname=foo_h.db', {
       tbl => 't_tie_analysis',
       key => 'h_key',
       fld => 'h_value'
    };

 use DBD::CSV;

 tie my %h2, 'MCE::Shared', { module => 'Tie::Hash::DBD'},
    'dbi:CSV:f_dir=.;f_ext=.csv/r;csv_null=1;csv_decode_utf8=0', {
       tbl => 'mytable',
       key => 'h_key',
       fld => 'h_value'
    };

 # By default, Sereal 3.015+ is used for serialization if available.
 # This overrides serialization from Sereal-or-Storable to JSON::XS.

 use JSON::XS ();

 tied(%h2)->encoder( \&JSON::XS::encode_json );
 tied(%h2)->decoder( \&JSON::XS::decode_json );

 my @pairs = ( key1 => 'val1', key2 => 'val2' );
 my @list  = ( 1, 2, 3, 4 );

 $h2{'foo'} = 'plain value';
 $h2{'bar'} = { @pairs };
 $h2{'baz'} = [ @list ];

DB cursors, filters, and duplicate keys are not supported, just plain array and hash functionality. The OO interface provides better performance when needed. Use "iterator" or "next" for iterating over the elements.

 use MCE::Hobo;
 use MCE::Shared;
 use Fcntl;
 use DB_File;

 unlink 'foo_a';

 my $ob = tie my %h1, 'MCE::Shared', { module => 'DB_File' },
    'foo_a', O_CREAT|O_RDWR, 0640, $DB_HASH or die "open error: $!";

 $h1{key} = 'value';
 my $val = $h1{key};

 while ( my ($k, $v) = each %h1 ) {
    print "1: $k => $v\n";
 }

 # object oriented fashion, faster

 tied(%h1)->STORE( key1 => 'value1' );
 my $val1 = tied(%h1)->FETCH('key1');

 $ob->STORE( key2 => 'value2' );
 my $val2 = $ob->FETCH('key2');

 # non-parallel iteration

 my $iter = $ob->iterator;
 while ( my ($k, $v) = $iter->() ) {
    print "2: $k => $v\n";
 }

 # parallel iteration

 sub task {
    while ( my ($k, $v) = $ob->next ) {
       print "[$$] $k => $v\n";
       sleep 1;
    }
 }

 MCE::Hobo->create(\&task) for 1 .. 3;
 MCE::Hobo->waitall;

 $ob->rewind;

 # undef $ob and $iter before %h1 when destroying manually

 undef $ob;
 undef $iter;

 untie %h1;

See also Tie::File Demonstration, at the end of the documentation.

MCE::Shared->pdl_byte
MCE::Shared->pdl_short
MCE::Shared->pdl_ushort
MCE::Shared->pdl_long
MCE::Shared->pdl_longlong
MCE::Shared->pdl_float
MCE::Shared->pdl_double
MCE::Shared->pdl_ones
MCE::Shared->pdl_random
MCE::Shared->pdl_sequence
MCE::Shared->pdl_zeroes
MCE::Shared->pdl_indx
MCE::Shared->pdl

Sugar syntax for PDL construction to take place under the shared-manager process. The helper routines are made available only if "PDL" is loaded before "MCE::Shared".

 use PDL;
 use MCE::Shared;

 # This makes an extra copy, transfer, including destruction.
 my $ob1 = MCE::Shared->share( zeroes( 256, 256 ) );

 # Do this instead to not involve an extra copy.
 my $ob1 = MCE::Shared->pdl_zeroes( 256, 256 );

Below is a parallel version for a demonstration on PerlMonks.

 # https://www.perlmonks.org/?node_id=1214227 (by vr)

 use strict;
 use warnings;
 use feature 'say';

 use PDL;  # must load PDL before MCE::Shared

 use MCE;
 use MCE::Shared;
 use Time::HiRes 'time';

 srand( 123 );

 my $time = time;

 my $n = 30000;      # input sample size
 my $m = 10000;      # number of bootstrap repeats
 my $r = $n;         # re-sample size

 # On Windows, the non-shared piddle ($x) is unblessed in threads.
 # Therefore, constructing the piddle inside the worker.
 # UNIX platforms benefit from copy-on-write. Thus, one copy.

 my $x   = ( $^O eq 'MSWin32' ) ? undef : random( $n );
 my $avg = MCE::Shared->pdl_zeroes( $m );

 MCE->new(
    max_workers => 4,
    sequence    => [ 0, $m - 1 ],
    chunk_size  => 1,
    user_begin  => sub {
       $x = random( $n ) unless ( defined $x );
    },
    user_func   => sub {
       my $idx  = random $r;
       $idx    *= $n;
       # $avg is a shared piddle which resides inside the shared-
       # manager process or thread. The piddle is accessible via the
       # OO interface only.
       $avg->set( $_, $x->index( $idx )->avg );
    }
 )->run;

 # MCE sets the seed of the base generator uniquely between workers.
 # Unfortunately, it requires running with one worker for predictable
 # results (i.e. no guarantee in the order which worker computes the
 # next input chunk).

 say $avg->pctover( pdl 0.05, 0.95 );
 say time - $time, ' seconds';

 __END__

 # Output

 [0.49387106  0.4993768]
 1.09556317329407 seconds
ins_inplace

The "ins_inplace" method applies to shared PDL objects. It supports three forms for writing elements back to the PDL object, residing under the shared-manager process.

 # --- action taken by the shared-manager process
 # ins_inplace(  1 arg  ):  ins( inplace( $this ), $what, 0, 0 );
 # ins_inplace(  2 args ):  $this->slice( $arg1 ) .= $arg2;
 # ins_inplace( >2 args ):  ins( inplace( $this ), $what, @coords );

 # --- use case
 $o->ins_inplace( $result );                    #  1 arg
 $o->ins_inplace( ":,$start:$stop", $result );  #  2 args
 $o->ins_inplace( $result, 0, $seq_n );         # >2 args

Operations such as " + 5 " will not work on shared PDL objects. At this time, the OO interface is the only mechanism for communicating with the shared piddle. For example, call "slice", "sever", or "copy" to fetch elements. Call "ins_inplace" or "set" (shown above) to update elements.

 use strict;
 use warnings;

 use PDL;  # must load PDL before MCE::Shared
 use MCE::Shared;

 # make a shared piddle
 my $b = MCE::Shared->pdl_sequence(15,15);

 # fetch, add 10 to row 2 only
 my $res1 = $b->slice(":,1:1") + 10;
 $b->ins_inplace($res1, 0, 1);

 # fetch, add 10 to rows 4 and 5
 my $res2 = $b->slice(":,3:4") + 10;
 $b->ins_inplace($res2, 0, 3);

 # make non-shared object (i.e. export-destroy from shared)
 $b = $b->destroy;

 print "$b\n";

The following provides parallel demonstrations using "MCE::Flow".

 use strict;
 use warnings;

 use PDL;  # must load PDL before MCE::Shared

 use MCE::Flow;
 use MCE::Shared;

 # On Windows, the ($a) piddle is unblessed in worker threads.
 # Therefore, constructing ($a) inside the worker versus sharing.
 # UNIX platforms benefit from copy-on-write. Thus, one copy.
 #
 # Results are stored in the shared piddle ($b).

 my $a = ( $^O eq 'MSWin32' ) ? undef : sequence(15,15);
 my $b = MCE::Shared->pdl_zeroes(15,15);

 MCE::Flow->init(
    user_begin => sub {
       $a = sequence(15,15) unless ( defined $a );
    }
 );

 # with chunking disabled

 mce_flow_s {
    max_workers => 4, chunk_size => 1
 },
 sub {
    my $row = $_;
    my $result = $a->slice(":,$row:$row") + 5;
    $b->ins_inplace($result, 0, $row);
 }, 0, 15 - 1;

 # with chunking enabled

 mce_flow_s {
    max_workers => 4, chunk_size => 5, bounds_only => 1
 },
 sub {
    my ($row1, $row2) = @{ $_ };
    my $result = $a->slice(":,$row1:$row2") + 5;
    $b->ins_inplace($result, 0, $row1);
 }, 0, 15 - 1;

 # make non-shared object, export-destroy the shared object

 $b = $b->destroy;

 print "$b\n";

See also PDL::ParallelCPU and PDL::Parallel::threads. For further reading, the MCE-Cookbook on GitHub provides two PDL demonstrations.

<https://github.com/marioroy/mce-cookbook>

blessed
Returns the real "blessed" name, provided by the shared-manager process.

 use MCE::Shared;
 use Scalar::Util qw(blessed);

 my $oh1 = MCE::Shared->share({ module => 'MCE::Shared::Ordhash' });
 my $oh2 = MCE::Shared->share({ module => 'Hash::Ordered'        });

 print blessed($oh1), "\n";    # MCE::Shared::Object
 print blessed($oh2), "\n";    # MCE::Shared::Object

 print $oh1->blessed(), "\n";  # MCE::Shared::Ordhash
 print $oh2->blessed(), "\n";  # Hash::Ordered
    
destroy ( { unbless => 1 } )
destroy
Exports optionally, but destroys the shared object entirely from the shared-manager process. The unbless option is passed to export.

 my $exported_ob = $shared_ob->destroy();

 $shared_ob;     # becomes undef
    
lock
unlock
Shared objects embed a MCE::Mutex object for locking since 1.841.

 use MCE::Shared;

 tie my @shared_array, 'MCE::Shared', { module => 'MCE::Shared::Array' }, 0;

 tied(@shared_array)->lock;
 $shared_array[0] += 1;
 tied(@shared_array)->unlock;

 print $shared_array[0], "\n";    # 1
    

Locking is not necessary typically when using the OO interface. Although, exclusive access is necessary when involving a FETCH and STORE.

 my $shared_total = MCE::Shared->scalar(2);

 $shared_total->lock;
 my $val = $shared_total->get;
 $shared_total->set( $val * 2 );
 $shared_total->unlock;

 print $shared_total->get, "\n";  # 4
    
encoder ( CODE )
decoder ( CODE )
Override freeze/thaw routines. Applies to STORE and FETCH only, particularly for TIE'd objects. These are called internally for shared DB objects.

Current API available since 1.827.

 use MCE::Shared;
 use BerkeleyDB;
 use DB_File;

 my $file1 = 'file1.db';
 my $file2 = 'file2.db';

 tie my @db1, 'MCE::Shared', { module => 'DB_File' }, $file1,
    O_RDWR|O_CREAT, 0640 or die "open error '$file1': $!";

 tie my %db2, 'MCE::Shared', { module => 'BerkeleyDB::Hash' },
    -Filename => $file2, -Flags => DB_CREATE
    or die "open error '$file2': $!";

 # Called automatically by MCE::Shared for DB files.
 # tied(@db1)->encoder( MCE::Shared::Server::_get_freeze );
 # tied(@db1)->decoder( MCE::Shared::Server::_get_thaw );
 # tied(%db2)->encoder( MCE::Shared::Server::_get_freeze );
 # tied(%db2)->decoder( MCE::Shared::Server::_get_thaw );
 # et cetera.

 $db1[0] = 'foo';   # store plain and complex structure
 $db1[1] = { key => 'value' };
 $db1[2] = [ 'complex' ];

 $db2{key} = 'foo'; # ditto, plain and complex structure
 $db2{sun} = [ 'complex' ];
    
export ( { unbless => 1 }, keys )
export
Exports the shared object as a non-shared object. One must export the shared object when passing into any dump routine. Otherwise, the "shared_id value" and "blessed name" is all one will see. The unbless option unblesses any shared Array, Hash, and Scalar object to a non-blessed array, hash, and scalar respectively.

 use MCE::Shared;
 use MCE::Shared::Ordhash;

 sub _dump {
    require Data::Dumper unless $INC{'Data/Dumper.pm'};
    no warnings 'once';

    local $Data::Dumper::Varname  = 'VAR';
    local $Data::Dumper::Deepcopy = 1;
    local $Data::Dumper::Indent   = 1;
    local $Data::Dumper::Purity   = 1;
    local $Data::Dumper::Sortkeys = 0;
    local $Data::Dumper::Terse    = 0;

    print Data::Dumper::Dumper($_[0]) . "\n";
 }

 my $oh1 = MCE::Shared->share({ module => 'MCE::Shared::Ordhash' });
 my $oh2 = MCE::Shared->ordhash();  # same thing

 _dump($oh1);
    # bless( [ 1, 'MCE::Shared::Ordhash' ], 'MCE::Shared::Object' )

 _dump($oh2);
    # bless( [ 2, 'MCE::Shared::Ordhash' ], 'MCE::Shared::Object' )

 _dump( $oh1->export );  # dumps object structure and content
 _dump( $oh2->export );  # ditto
    

"export" can optionally take a list of indices/keys for what to export. This applies to shared array, hash, and ordhash.

 use MCE::Shared;

 # shared hash
 my $h1 = MCE::Shared->hash(
    qw/ I Heard The Bluebirds Sing by Marty Robbins /
      # k v     k   v         k    v  k     v
 );

 # non-shared hash
 my $h2 = $h1->export( qw/ I The / );

 _dump($h2);

 __END__

 # Output

 $VAR1 = bless( {
   'I' => 'Heard',
   'The' => 'Bluebirds'
 }, 'MCE::Shared::Hash' );
    

Specifying the unbless option exports a non-blessed data structure instead. The unbless option applies to shared MCE::Shared::{ Array, Hash, and Scalar } objects.

 my $h2 = $h1->export( { unbless => 1 }, qw/ I The / );
 my $h3 = $h1->export( { unbless => 1 } );

 _dump($h2);
 _dump($h3);

 __END__

 # Output

 $VAR1 = {
   'The' => 'Bluebirds',
   'I' => 'Heard'
 };

 $VAR1 = {
   'Marty' => 'Robbins',
   'Sing' => 'by',
   'The' => 'Bluebirds',
   'I' => 'Heard'
 };
    
next
The "next" method provides parallel iteration between workers for shared "array", "hash", "ordhash", and "sequence". In list context, returns the next key-value pair or beg-end pair for sequence. In scalar context, returns the next item. The "undef" value is returned after the iteration has completed.

Internally, the list of keys to return is set when the closure is constructed. Later keys added to the shared array or hash are not included. Subsequently, the "undef" value is returned for deleted keys.

The following example iterates through a shared array in parallel.

 use MCE::Hobo;
 use MCE::Shared;

 my $ar = MCE::Shared->array( 'a' .. 'j' );

 sub demo1 {
    my ( $wid ) = @_;
    while ( my ( $index, $value ) = $ar->next ) {
       print "$wid: [ $index ] $value\n";
       sleep 1;
    }
 }

 sub demo2 {
    my ( $wid ) = @_;
    while ( defined ( my $value = $ar->next ) ) {
       print "$wid: $value\n";
       sleep 1;
    }
 }

 $ar->rewind();

 MCE::Hobo->new( \&demo1, $_ ) for 1 .. 3;
 MCE::Hobo->waitall(), print "\n";

 $ar->rewind();

 MCE::Hobo->new( \&demo2, $_ ) for 1 .. 3;
 MCE::Hobo->waitall(), print "\n";

 __END__

 # Output

 1: [ 0 ] a
 2: [ 1 ] b
 3: [ 2 ] c
 1: [ 3 ] d
 2: [ 5 ] f
 3: [ 4 ] e
 2: [ 8 ] i
 3: [ 6 ] g
 1: [ 7 ] h
 2: [ 9 ] j

 1: a
 2: b
 3: c
 2: e
 3: f
 1: d
 3: g
 1: i
 2: h
 1: j
    

The form is similar for "sequence". For large sequences, the "bounds_only" option is recommended. Also, specify "chunk_size" accordingly. This reduces the amount of traffic to and from the shared-manager process.

 use MCE::Hobo;
 use MCE::Shared;

 my $N   = shift || 4_000_000;
 my $pi  = MCE::Shared->scalar( 0.0 );

 my $seq = MCE::Shared->sequence(
    { chunk_size => 200_000, bounds_only => 1 }, 0, $N - 1
 );

 sub compute_pi {
    my ( $wid ) = @_;

    # Optionally, also receive the chunk_id value
    # while ( my ( $beg, $end, $chunk_id ) = $seq->next ) { ... }

    while ( my ( $beg, $end ) = $seq->next ) {
       my ( $_pi, $t ) = ( 0.0 );
       for my $i ( $beg .. $end ) {
          $t = ( $i + 0.5 ) / $N;
          $_pi += 4.0 / ( 1.0 + $t * $t );
       }
       $pi->incrby( $_pi );
    }

    return;
 }

 MCE::Hobo->create( \&compute_pi, $_ ) for ( 1 .. 8 );

 # ... do other stuff ...

 MCE::Hobo->waitall();

 printf "pi = %0.13f\n", $pi->get / $N;

 __END__

 # Output

 3.1415926535898
    
rewind ( index, [, index, ... ] )
rewind ( key, [, key, ... ] )
rewind ( "query string" )
rewind ( )
Rewinds the parallel iterator for MCE::Shared::Array, MCE::Shared::Hash, or MCE::Shared::Ordhash when no arguments are given. Otherwise, resets the iterator with given criteria. The syntax for "query string" is described in the shared module.

 # array
 $ar->rewind;

 $ar->rewind( 0, 1 );
 $ar->rewind( "val eq some_value" );
 $ar->rewind( "key >= 50 :AND val =~ /sun|moon|air|wind/" );
 $ar->rewind( "val eq sun :OR val eq moon :OR val eq foo" );
 $ar->rewind( "key =~ /$pattern/" );

 while ( my ( $index, $value ) = $ar->next ) {
    ...
 }

 # hash, ordhash
 $oh->rewind;

 $oh->rewind( "key1", "key2" );
 $oh->rewind( "val eq some_value" );
 $oh->rewind( "key eq some_key :AND val =~ /sun|moon|air|wind/" );
 $oh->rewind( "val eq sun :OR val eq moon :OR val eq foo" );
 $oh->rewind( "key =~ /$pattern/" );

 while ( my ( $key, $value ) = $oh->next ) {
    ...
 }
    
rewind ( { options }, begin, end [, step, format ] )
rewind ( begin, end [, step, format ] )
rewind ( )
Rewinds the parallel iterator for MCE::Shared::Sequence when no arguments are given. Otherwise, resets the iterator with given criteria.

 # sequence
 $seq->rewind;

 $seq->rewind( { chunk_size => 10, bounds_only => 1 }, 1, 100 );

 while ( my ( $beg, $end ) = $seq->next ) {
    for my $i ( $beg .. $end ) {
       ...
    }
 }

 $seq->rewind( 1, 100 );

 while ( defined ( my $num = $seq->next ) ) {
    ...
 }
    
store ( key, value )
Deeply sharing a non-blessed structure recursively is possible with "store", an alias to "STORE".

 use MCE::Shared;

 my $h1 = MCE::Shared->hash();
 my $h2 = MCE::Shared->hash();

 # auto-shares deeply
 $h1->store('key', [ 0, 2, 5, { 'foo' => 'bar' } ]);
 $h2->{key}[3]{foo} = 'baz';    # via auto-vivification

 my $v1 = $h1->get('key')->get(3)->get('foo');  # bar
 my $v2 = $h2->get('key')->get(3)->get('foo');  # baz
 my $v3 = $h2->{key}[3]{foo};                   # baz
    

init
This method is called by each MCE and Hobo worker automatically after spawning. The effect is extra parallelism and decreased latency during inter-process communication to the shared-manager process. The optional ID (an integer) is modded internally in a round-robin fashion.

 MCE::Shared->init();
 MCE::Shared->init( ID );
    
pid
Returns the process ID of the shared-manager process. This class method was added in 1.849 for stopping all workers immediately when exiting a Graphics::Framebuffer application. It returns an undefined value if the shared-manager is not running. Not useful otherwise if running threads (i.e. same PID).

 MCE::Shared->pid();

 $SIG{INT} = $SIG{HUP} = $SIG{TERM} = sub {
    # Signal workers and the shared manager all at once
    CORE::kill('KILL', MCE::Hobo->list_pids(), MCE::Shared->pid());
    exec('reset');
 };
    
start
Starts the shared-manager process. This is done automatically unless Perl lacks IO::FDPass, needed to share "condvar" and "queue" while the shared-manager is running.

 MCE::Shared->start();
    
stop
Stops the shared-manager process, wiping all shared data content. This is called by the "END" block automatically when the script terminates. However, do stop explicitly to reap the shared-manager process before exec'ing.

 MCE::Shared->stop();

 exec('command');
    

Application-level advisory locking is possible with MCE::Mutex.

 use MCE::Hobo;
 use MCE::Mutex;
 use MCE::Shared;

 my $mutex = MCE::Mutex->new();

 tie my $cntr, 'MCE::Shared', 0;

 sub work {
    for ( 1 .. 1000 ) {
       $mutex->lock;

       # Incrementing involves 2 IPC ops ( FETCH and STORE ).
       # Thus, locking is required.
       $cntr++;

       $mutex->unlock;
    }
 }

 MCE::Hobo->create('work') for ( 1 .. 8 );
 MCE::Hobo->waitall;

 print $cntr, "\n"; # 8000

Locking is available for shared objects via "lock" and "unlock" methods since 1.841. Previously, for "condvar" only.

 use MCE::Hobo;
 use MCE::Shared;

 tie my $cntr, 'MCE::Shared', 0;

 sub work {
    for ( 1 .. 1000 ) {
       tied($cntr)->lock;

       # Incrementing involves 2 IPC ops ( FETCH and STORE ).
       # Thus, locking is required.
       $cntr++;

       tied($cntr)->unlock;
    }
 }

 MCE::Hobo->create('work') for ( 1 .. 8 );
 MCE::Hobo->waitall;

 print $cntr, "\n"; # 8000

Typically, locking is not necessary using the OO interface. The reason is that MCE::Shared is implemented using a single-point of entry for commands sent to the shared-manager process. Furthermore, the shared classes include sugar methods for combining set and get in a single operation.

 use MCE::Hobo;
 use MCE::Shared;

 my $cntr = MCE::Shared->scalar( 0 );

 sub work {
    for ( 1 .. 1000 ) {
       # The next statement increments the value without having
       # to call set and get explicitly.
       $cntr->incr;
    }
 }

 MCE::Hobo->create('work') for ( 1 .. 8 );
 MCE::Hobo->waitall;

 print $cntr->get, "\n"; # 8000

Another possibility when running threads is locking via threads::shared.

 use threads;
 use threads::shared;

 use MCE::Flow;
 use MCE::Shared;

 my $mutex : shared;

 tie my $cntr, 'MCE::Shared', 0;

 sub work {
    for ( 1 .. 1000 ) {
       lock $mutex;

       # the next statement involves 2 IPC ops ( get and set )
       # thus, locking is required
       $cntr++;
    }
 }

 MCE::Flow->run( { max_workers => 8 }, \&work );
 MCE::Flow->finish;

 print $cntr, "\n"; # 8000

Of the three demonstrations, the OO interface yields the best performance. This is from the lack of locking at the application level. The results were obtained from a MacBook Pro (Haswell) running at 2.6 GHz, 1600 MHz RAM.

 CentOS 7.2 VM

    -- Perl v5.16.3
    MCE::Mutex .... : 0.528 secs.
    OO Interface .. : 0.062 secs.
    threads::shared : 0.545 secs.

 FreeBSD 10.0 VM

    -- Perl v5.16.3
    MCE::Mutex .... : 0.367 secs.
    OO Interface .. : 0.083 secs.
    threads::shared : 0.593 secs.

 Mac OS X 10.11.6 ( Host OS )

    -- Perl v5.18.2
    MCE::Mutex .... : 0.397 secs.
    OO Interface .. : 0.070 secs.
    threads::shared : 0.463 secs.

 Solaris 11.2 VM

    -- Perl v5.12.5 installed with the OS
    MCE::Mutex .... : 0.895 secs.
    OO Interface .. : 0.099 secs.
    threads::shared :              Perl not built to support threads

    -- Perl v5.22.2 built with threads support
    MCE::Mutex .... : 0.788 secs.
    OO Interface .. : 0.086 secs.
    threads::shared : 0.895 secs.

 Windows 7 VM

    -- Perl v5.22.2
    MCE::Mutex .... : 1.045 secs.
    OO Interface .. : 0.312 secs.
    threads::shared : 1.061 secs.

Beginning with MCE::Shared 1.809, the "pipeline" method provides another way. Included in "Array", "Cache", "Hash", "Minidb", and "Ordhash", it combines multiple commands for the object to be processed serially. For shared objects, the call is made atomically due to single IPC to the shared-manager process.

The "pipeline" method is fully "wantarray"-aware and receives a list of commands and their arguments. In scalar or list context, it returns data from the last command in the pipeline.

 use MCE::Mutex;
 use MCE::Shared;

 my $mutex = MCE::Mutex->new();
 my $oh = MCE::Shared->ordhash();
 my @vals;

 # mutex locking

 $mutex->lock;
 $oh->set( foo => "a_a" );
 $oh->set( bar => "b_b" );
 $oh->set( baz => "c_c" );
 @vals = $oh->mget( qw/ foo bar baz / );
 $mutex->unlock;

 # pipeline, same thing done atomically

 @vals = $oh->pipeline(
    [ "set", foo => "a_a" ],
    [ "set", bar => "b_b" ],
    [ "set", baz => "c_c" ],
    [ "mget", qw/ foo bar baz / ]
 );

 # ( "a_a", "b_b", "c_c" )

There is also "pipeline_ex", same as "pipeline", but returns data for every command in the pipeline.

 @vals = $oh->pipeline_ex(
    [ "set", foo => "a_a" ],
    [ "set", bar => "b_b" ],
    [ "set", baz => "c_c" ]
 );

 # ( "a_a", "b_b", "c_c" )

Sharing a Python class is possible, starting with the 1.827 release. The construction is simply calling share with the module option. Methods are accessible via the OO interface.

 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 # Python class.
 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 package My::Class;

 use strict;
 use warnings;

 use Inline::Python qw( py_eval py_bind_class );

 py_eval ( <<'END_OF_PYTHON_CLASS' );

 class MyClass:
     def __init__(self):
         self.data = [0,0]

     def set (self, key, value):
         self.data[key] = value

     def get (self, key):
         try: return self.data[key]
         except KeyError: return None

     def incr (self, key):
         try: self.data[key] = self.data[key] + 1
         except KeyError: self.data[key] = 1

 END_OF_PYTHON_CLASS

 # Register methods for best performance.

 py_bind_class(
     'My::Class', '__main__', 'MyClass',
     'set', 'get', 'incr'
 );

 1;

 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 # Share Python class. Requires MCE::Shared 1.827 or later.
 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 use strict;
 use warnings;

 use MCE::Hobo;
 use MCE::Shared;

 my $py1 = MCE::Shared->share({ module => 'My::Class' });
 my $py2 = MCE::Shared->share({ module => 'My::Class' });

 MCE::Shared->start;

 $py1->set(0, 100);
 $py2->set(1, 200);

 die "Ooops" unless $py1->get(0) eq '100';
 die "Ooops" unless $py2->get(1) eq '200';

 sub task {
     $py1->incr(0) for 1..50000;
     $py2->incr(1) for 1..50000;
 }

 MCE::Hobo->create(\&task) for 1..3;
 MCE::Hobo->waitall;

 print $py1->get(0), "\n";  # 150100
 print $py2->get(1), "\n";  # 150200

Often, the requirement may call for concurrent logging by many workers. Calling localtime or gmtime per each log entry is expensive. This uses the old time-stamp value until one second has elapsed.

 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 # Logger class.
 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 package My::Logger;

 use strict;
 use warnings;

 use Time::HiRes qw( time );

 # construction

 sub new {
     my ( $class, %self ) = @_;

     open $self{fh}, ">>", $self{path} or return '';
     binmode $self{fh};

     $self{stamp} = localtime;  # or gmtime
     $self{time } = time;

     bless \%self, $class;
 }

 # $ob->log("message");

 sub log {
     my ( $self, $stamp ) = ( shift );

     if ( time - $self->{time} > 1.0 ) {
         $self->{stamp} = $stamp = localtime;  # or gmtime
         $self->{time } = time;
     }
     else {
         $stamp = $self->{stamp};
     }

     print {$self->{fh}} "$stamp --- @_\n";
 }

 # $ob->autoflush(0);
 # $ob->autoflush(1);

 sub autoflush {
     my ( $self, $flag ) = @_;

     if ( defined fileno($self->{fh}) ) {
          $flag ? select(( select($self->{fh}), $| = 1 )[0])
                : select(( select($self->{fh}), $| = 0 )[0]);

          return 1;
     }

     return;
 }

 # $ob->binmode($layer);
 # $ob->binmode();

 sub binmode {
     my ( $self, $layer ) = @_;

     if ( defined fileno($self->{fh}) ) {
         CORE::binmode $self->{fh}, $layer // ':raw';

         return 1;
     }

     return;
 }

 # $ob->close()

 sub close {
     my ( $self ) = @_;

     if ( defined fileno($self->{fh}) ) {
         close $self->{'fh'};
     }

     return;
 }

 # $ob->flush()

 sub flush {
     my ( $self ) = @_;

     if ( defined fileno($self->{fh}) ) {
         my $old_fh = select $self->{fh};
         my $old_af = $|; $| = 1; $| = $old_af;
         select $old_fh;

         return 1;
     }

     return;
 }

 1;

 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 # Concurrent logger demo. Requires MCE::Shared 1.827 or later.
 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 use strict;
 use warnings;

 use MCE::Hobo;
 use MCE::Shared;

 my $file = "log.txt";
 my $pid  = $$;

 my $ob = MCE::Shared->share( { module => 'My::Logger' }, path => $file )
     or die "open error '$file': $!";

 # $ob->autoflush(1);   # optional, flush writes immediately

 sub work {
     my $id = shift;
     for ( 1 .. 250_000 ) {
         $ob->log("Hello from $id: $_");
     }
 }

 MCE::Hobo->create('work', $_) for 1 .. 4;
 MCE::Hobo->waitall;

 # Threads and multi-process safety for closing the handle.

 sub CLONE { $pid = 0; }

 END { $ob->close if $ob && $pid == $$; }

The following presents a concurrent Tie::File demonstration. Each element in the array corresponds to a record in the text file. JSON, being readable, seems appropiate for encoding complex objects.

 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 # Class extending Tie::File with two sugar methods.
 # Requires MCE::Shared 1.827 or later.
 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 package My::File;

 use strict;
 use warnings;

 use Tie::File;

 our @ISA = 'Tie::File';

 # $ob->append('string');

 sub append {
     my ($self, $key) = @_;
     my $val = $self->FETCH($key); $val .= $_[2];
     $self->STORE($key, $val);
     length $val;
 }

 # $ob->incr($key);

 sub incr {
     my ( $self, $key ) = @_;
     my $val = $self->FETCH($key); $val += 1;
     $self->STORE($key, $val);
     $val;
 }

 1;

 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 # The MCE::Mutex module isn't needed unless IPC involves two or
 # more trips for the underlying action.
 #~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 use strict;
 use warnings;

 use MCE::Hobo;
 use MCE::Mutex;
 use MCE::Shared;

 use JSON::MaybeXS;

 # Safety for data having line breaks.
 use constant EOL => "\x{0a}~\x{0a}";

 my $file  = 'file.txt';
 my $mutex = MCE::Mutex->new();
 my $pid   = $$;

 my $ob = tie my @db, 'MCE::Shared', { module => 'My::File' }, $file,
     recsep => EOL or die "open error '$file': $!";

 $ob->encoder( \&JSON::MaybeXS::encode_json );
 $ob->decoder( \&JSON::MaybeXS::decode_json );

 $db[20] = 0;  # a counter at offset 20 into the array
 $db[21] = [ qw/ foo bar / ];  # store complex structure

 sub task {
     my $id  = sprintf "%02s", shift;
     my $row = int($id) - 1;
     my $chr = sprintf "%c", 97 + $id - 1;

     # A mutex isn't necessary when storing a value.
     # Ditto for fetching a value.

     $db[$row] = "Hello from $id: ";  # 1 trip
     my $val   = length $db[$row];    # 1 trip

     # A mutex may be necessary for updates involving 2 or
     # more trips (FETCH and STORE) during IPC, from and to
     # the shared-manager process, unless a unique row.

     for ( 1 .. 40 ) {
       # $db[$row] .= $id;         # 2 trips, unique row - okay
         $ob->append($row, $chr);  # 1 trip via the OO interface

       # $mu->lock;
       # $db[20] += 1;             # incrementing counter, 2 trips
       # $mu->unlock;

         $ob->incr(20);            # same thing via OO, 1 trip
     }

     my $len = length $db[$row];   # 1 trip

     printf "hobo %2d : %d\n", $id, $len;
 }

 MCE::Hobo->create('task', $_) for 1 .. 20;
 MCE::Hobo->waitall;

 printf "counter : %d\n", $db[20];
 print  $db[21]->[0], "\n";  # foo

 # Threads and multi-process safety for closing the handle.

 sub CLONE { $pid = 0; }

 END {
     if ( $pid == $$ ) {
         undef $ob;  # important, undef $ob before @db
         untie @db;  # untie @db to flush pending writes
     }
 }

MCE::Shared requires Perl 5.10.1 or later. The IO::FDPass module is highly recommended on UNIX and Windows. This module does not install it by default.

The source, cookbook, and examples are hosted at GitHub.
  • <https://github.com/marioroy/mce-shared>
  • <https://github.com/marioroy/mce-cookbook>
  • <https://github.com/marioroy/mce-examples>

MCE, MCE::Hobo

Mario E. Roy, <marioeroy AT gmail DOT com>

Copyright (C) 2016-2022 by Mario E. Roy

MCE::Shared is released under the same license as Perl.

See <http://dev.perl.org/licenses/> for more information.

2022-02-20 perl v5.32.1

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