mirror of
https://github.com/moses-smt/mosesdecoder.git
synced 2024-12-29 15:04:05 +03:00
325 lines
8.7 KiB
Perl
Executable File
325 lines
8.7 KiB
Perl
Executable File
#!/usr/bin/perl -w
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binmode( STDIN, ":utf8" );
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binmode( STDOUT, ":utf8" );
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use strict;
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use FindBin qw($RealBin);
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use File::Basename;
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sub trim($);
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print STDERR "HELLO ";
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for ( my $i = 0 ; $i < scalar @ARGV ; ++$i ) {
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print STDERR $ARGV[$i] . " ";
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}
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print STDERR "GOODBYE \n";
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############################################
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# START
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my $inPath = $ARGV[0];
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open( IN, "<" . $inPath );
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open( RULE, ">$inPath.extract" );
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open( RULE_INV, ">$inPath.extract.inv" );
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my ( $sentenceInd, $score, $source, $input, $target, $align, $path, $count );
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# MAIN LOOP
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while ( $sentenceInd = <IN> ) {
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$score = <IN>;
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$source = <IN>;
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$input = <IN>;
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$target = <IN>;
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$align = <IN>;
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$path = <IN>;
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$count = <IN>;
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chomp($sentenceInd);
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chomp($score);
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chomp($source);
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chomp($input);
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chomp($target);
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chomp($align);
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chomp($path);
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chomp($count);
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$source = trim($sentenceInd);
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$source = trim($score);
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$source = trim($source);
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$input = trim($input);
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$target = trim($target);
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$align = trim($align);
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$path = trim($path);
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$count = trim($count);
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my ( $frame, $rule_s, $rule_t, $rule_alignment, $rule_alignment_inv ) =
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&create_xml( $source, $input, $target, $align, $path );
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#print STDOUT $frame."\n";
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print RULE "$rule_s [X] ||| $rule_t [X] ||| $rule_alignment ||| $count\n";
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print RULE_INV
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"$rule_t [X] ||| $rule_s [X] ||| $rule_alignment_inv ||| $count\n";
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#print STDOUT "$sentenceInd ||| $score ||| $count\n";
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}
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close(IN);
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close(RULE);
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close(RULE_INV);
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`LC_ALL=C sort $inPath.extract | gzip -c > $inPath.extract.sorted.gz`;
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`LC_ALL=C sort $inPath.extract.inv | gzip -c > $inPath.extract.inv.sorted.gz`;
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my $lex_file = "-";
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my $cmd;
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$cmd =
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"$RealBin/../../scripts/training/train-model.perl -dont-zip -first-step 6 -last-step 6 -f en -e fr -hierarchical -extract-file $inPath.extract -lexical-file $lex_file -score-options \"--NoLex\" -phrase-translation-table $inPath.pt";
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print STDERR "Executing: $cmd \n";
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`$cmd`;
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#######################################################
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sub create_xml {
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my ( $source, $input, $target, $alignment, $path ) = @_;
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my @INPUT = split( / /, $input );
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my @SOURCE = split( / /, $source );
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my @TARGET = split( / /, $target );
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my %ALIGN = &create_alignment($alignment);
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my %FRAME_INPUT;
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my ( @NT, @INPUT_BITMAP, @TARGET_BITMAP, %ALIGNMENT_I_TO_S );
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foreach (@TARGET) { push @TARGET_BITMAP, 1 }
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### STEP 1: FIND MISMATCHES
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my ( $s, $i ) = ( 0, 0 );
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my $currently_matching = 0;
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my ( $start_s, $start_i ) = ( 0, 0 );
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$path .= "X"; # indicate end
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print STDERR "$input\n$source\n$target\n$path\n";
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for ( my $p = 0 ; $p < length($path) ; $p++ ) {
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my $action = substr( $path, $p, 1 );
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# beginning of a mismatch
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if ( $currently_matching && $action ne "M" && $action ne "X" ) {
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$start_i = $i;
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$start_s = $s;
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$currently_matching = 0;
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}
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# end of a mismatch
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elsif ( !$currently_matching
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&& ( $action eq "M" || $action eq "X" ) )
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{
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# remove use of affected target words
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for ( my $ss = $start_s ; $ss < $s ; $ss++ ) {
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foreach my $tt ( keys %{ ${ $ALIGN{'s'} }[$ss] } ) {
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$TARGET_BITMAP[$tt] = 0;
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}
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# also remove enclosed unaligned words?
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}
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# are there input words that need to be inserted ?
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print STDERR "($start_i<$i)?\n";
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if ( $start_i < $i ) {
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# take note of input words to be inserted
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my $insertion = "";
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for ( my $ii = $start_i ; $ii < $i ; $ii++ ) {
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$insertion .= $INPUT[$ii] . " ";
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}
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# find position for inserted input words
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# find first removed target word
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my $start_t = 1000;
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for ( my $ss = $start_s ; $ss < $s ; $ss++ ) {
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foreach my $tt ( keys %{ ${ $ALIGN{'s'} }[$ss] } ) {
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$start_t = $tt if $tt < $start_t;
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}
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}
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# end of sentence? add to end
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if ( $start_t == 1000 && $i > $#INPUT ) {
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$start_t = $#TARGET;
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}
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# backtrack to previous words if unaligned
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if ( $start_t == 1000 ) {
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$start_t = -1;
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for ( my $ss = $s - 1 ; $start_t == -1 && $ss >= 0 ; $ss-- ) {
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foreach my $tt ( keys %{ ${ $ALIGN{'s'} }[$ss] } ) {
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$start_t = $tt if $tt > $start_t;
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}
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}
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}
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$FRAME_INPUT{$start_t} .= $insertion;
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my %NT = (
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"start_t" => $start_t,
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"start_i" => $start_i
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);
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push @NT, \%NT;
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}
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$currently_matching = 1;
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}
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print STDERR "$action $s $i ($start_s $start_i) $currently_matching";
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if ( $action ne "I" ) {
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print STDERR " ->";
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foreach my $tt ( keys %{ ${ $ALIGN{'s'} }[$s] } ) {
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print STDERR " " . $tt;
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}
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}
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print STDERR "\n";
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$s++ unless $action eq "I";
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$i++ unless $action eq "D";
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$ALIGNMENT_I_TO_S{$i} = $s unless $action eq "D";
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push @INPUT_BITMAP, 1 if $action eq "M";
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push @INPUT_BITMAP, 0 if $action eq "I" || $action eq "S";
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}
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print STDERR $target . "\n";
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foreach (@TARGET_BITMAP) { print STDERR $_; }
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print STDERR "\n";
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foreach ( sort keys %FRAME_INPUT ) {
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print STDERR "$_: $FRAME_INPUT{$_}\n";
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}
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### STEP 2: BUILD RULE AND FRAME
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# hierarchical rule
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my $rule_s = "";
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my $rule_pos_s = 0;
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my %RULE_ALIGNMENT_S;
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for ( my $i = 0 ; $i < scalar(@INPUT_BITMAP) ; $i++ ) {
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if ( $INPUT_BITMAP[$i] ) {
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$rule_s .= $INPUT[$i] . " ";
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$RULE_ALIGNMENT_S{ $ALIGNMENT_I_TO_S{$i} } = $rule_pos_s++;
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}
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foreach my $NT (@NT) {
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if ( $i == $$NT{"start_i"} ) {
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$rule_s .= "[X][X] ";
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$$NT{"rule_pos_s"} = $rule_pos_s++;
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}
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}
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}
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my $rule_t = "";
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my $rule_pos_t = 0;
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my %RULE_ALIGNMENT_T;
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for ( my $t = -1 ; $t < scalar(@TARGET_BITMAP) ; $t++ ) {
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if ( $t >= 0 && $TARGET_BITMAP[$t] ) {
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$rule_t .= $TARGET[$t] . " ";
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$RULE_ALIGNMENT_T{$t} = $rule_pos_t++;
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}
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foreach my $NT (@NT) {
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if ( $t == $$NT{"start_t"} ) {
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$rule_t .= "[X][X] ";
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$$NT{"rule_pos_t"} = $rule_pos_t++;
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}
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}
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}
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my $rule_alignment = "";
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foreach my $s ( sort { $a <=> $b } keys %RULE_ALIGNMENT_S ) {
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foreach my $t ( keys %{ $ALIGN{"s"}[$s] } ) {
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next unless defined( $RULE_ALIGNMENT_T{$t} );
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$rule_alignment .=
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$RULE_ALIGNMENT_S{$s} . "-" . $RULE_ALIGNMENT_T{$t} . " ";
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}
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}
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foreach my $NT (@NT) {
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$rule_alignment .= $$NT{"rule_pos_s"} . "-" . $$NT{"rule_pos_t"} . " ";
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}
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chop($rule_s);
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chop($rule_t);
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chop($rule_alignment);
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my $rule_alignment_inv = "";
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foreach ( split( / /, $rule_alignment ) ) {
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/^(\d+)\-(\d+)$/;
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$rule_alignment_inv .= "$2-$1 ";
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}
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chop($rule_alignment_inv);
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# frame
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my $frame = "";
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$frame = $FRAME_INPUT{-1} if defined $FRAME_INPUT{-1};
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my $currently_included = 0;
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my $start_t = -1;
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push @TARGET_BITMAP, 0; # indicate end
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for ( my $t = 0 ; $t <= scalar(@TARGET) ; $t++ ) {
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# beginning of tm target inclusion
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if ( !$currently_included && $TARGET_BITMAP[$t] ) {
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$start_t = $t;
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$currently_included = 1;
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}
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# end of tm target inclusion (not included word or inserted input)
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elsif ( $currently_included
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&& ( !$TARGET_BITMAP[$t] || defined( $FRAME_INPUT{$t} ) ) )
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{
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# add xml (unless change is at the beginning of the sentence
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if ( $start_t >= 0 ) {
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my $target = "";
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print STDERR "for(tt=$start_t;tt<$t+$TARGET_BITMAP[$t]);\n";
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for ( my $tt = $start_t ; $tt < $t + $TARGET_BITMAP[$t] ; $tt++ ) {
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$target .= $TARGET[$tt] . " ";
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}
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chop($target);
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$frame .= "<xml translation=\"$target\"> x </xml> ";
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}
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$currently_included = 0;
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}
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$frame .= $FRAME_INPUT{$t} if defined $FRAME_INPUT{$t};
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print STDERR "$TARGET_BITMAP[$t] $t ($start_t) $currently_included\n";
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}
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print STDERR $frame . "\n-------------------------------------\n";
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return ( $frame, $rule_s, $rule_t, $rule_alignment, $rule_alignment_inv );
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}
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sub create_alignment {
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my ($line) = @_;
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my ( @ALIGNED_TO_S, @ALIGNED_TO_T );
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foreach my $point ( split( / /, $line ) ) {
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my ( $s, $t ) = split( /\-/, $point );
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$ALIGNED_TO_S[$s]{$t}++;
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$ALIGNED_TO_T[$t]{$s}++;
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}
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my %ALIGNMENT = ( 's' => \@ALIGNED_TO_S, 't' => \@ALIGNED_TO_T );
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return %ALIGNMENT;
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}
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# Perl trim function to remove whitespace from the start and end of the string
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sub trim($) {
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my $string = shift;
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$string =~ s/^\s+//;
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$string =~ s/\s+$//;
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return $string;
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}
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# Left trim function to remove leading whitespace
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sub ltrim($) {
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my $string = shift;
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$string =~ s/^\s+//;
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return $string;
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}
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# Right trim function to remove trailing whitespace
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sub rtrim($) {
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my $string = shift;
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$string =~ s/\s+$//;
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return $string;
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}
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