use Graph::Easy;
use IPC::Run qw( run binary );
+use Text::Tradition::Collation::Path;
+use Text::Tradition::Collation::Position;
use Text::Tradition::Collation::Reading;
+use Text::Tradition::Collation::Relationship;
+use Text::Tradition::Collation::Segment;
+use XML::LibXML;
use Moose;
has 'graph' => (
reading => 'node',
path => 'edge',
readings => 'nodes',
+ segments => 'nodes',
paths => 'edges',
+ relationships => 'edges',
},
default => sub { Graph::Easy->new( undirected => 0 ) },
);
-has 'tradition' => (
+has 'tradition' => ( # TODO should this not be ro?
is => 'rw',
isa => 'Text::Tradition',
);
predicate => 'has_svg',
);
-has 'graphviz' => (
+has 'graphml' => (
is => 'ro',
isa => 'Str',
- writer => '_save_graphviz',
- predicate => 'has_graphviz',
+ writer => '_save_graphml',
+ predicate => 'has_graphml',
);
-has 'graphml' => (
+# Keeps track of the lemmas within the collation. At most one lemma
+# per position in the graph.
+has 'lemmata' => (
is => 'ro',
- isa => 'XML::LibXML::Document',
- writer => '_save_graphml',
- predicate => 'has_graphml',
+ isa => 'HashRef[Maybe[Str]]',
+ default => sub { {} },
);
has 'wit_list_separator' => (
- is => 'rw',
- isa => 'Str',
- default => ', ',
- );
+ is => 'rw',
+ isa => 'Str',
+ default => ', ',
+ );
+
+has 'baselabel' => (
+ is => 'rw',
+ isa => 'Str',
+ default => 'base text',
+ );
+
+has 'collapsed' => (
+ is => 'rw',
+ isa => 'Bool',
+ );
+
+has 'linear' => (
+ is => 'rw',
+ isa => 'Bool',
+ default => 1,
+ );
+
+has 'ac_label' => (
+ is => 'rw',
+ isa => 'Str',
+ default => ' (a.c.)',
+ );
+
# The collation can be created two ways:
# 1. Collate a set of witnesses (with CollateX I guess) and process
sub BUILD {
my( $self, $args ) = @_;
$self->graph->use_class('node', 'Text::Tradition::Collation::Reading');
+ $self->graph->use_class('edge', 'Text::Tradition::Collation::Path');
# Pass through any graph-specific options.
my $shape = exists( $args->{'shape'} ) ? $args->{'shape'} : 'ellipse';
$self->graph->set_attribute( 'node', 'shape', $shape );
}
-# Wrappers around some methods
+# Wrapper around add_path
+
+around add_path => sub {
+ my $orig = shift;
+ my $self = shift;
+
+ # Make sure there are three arguments
+ unless( @_ == 3 ) {
+ warn "Call add_path with args source, target, witness";
+ return;
+ }
+ # Make sure the proposed path does not yet exist
+ # NOTE 'reading' will currently return readings and segments
+ my( $source, $target, $wit ) = @_;
+ $source = $self->reading( $source )
+ unless ref( $source ) eq 'Text::Tradition::Collation::Reading';
+ $target = $self->reading( $target )
+ unless ref( $target ) eq 'Text::Tradition::Collation::Reading';
+ foreach my $path ( $source->edges_to( $target ) ) {
+ if( $path->label eq $wit && $path->class eq 'edge.path' ) {
+ return;
+ }
+ }
+ # Do the deed
+ $self->$orig( @_ );
+};
+
+# Wrapper around paths
+around paths => sub {
+ my $orig = shift;
+ my $self = shift;
+
+ my @result = grep { $_->sub_class eq 'path' } $self->$orig( @_ );
+ return @result;
+};
+
+around relationships => sub {
+ my $orig = shift;
+ my $self = shift;
+ my @result = grep { $_->sub_class eq 'relationship' } $self->$orig( @_ );
+ return @result;
+};
+
+around readings => sub {
+ my $orig = shift;
+ my $self = shift;
+ my @result = grep { $_->sub_class ne 'segment' } $self->$orig( @_ );
+ return @result;
+};
+
+around segments => sub {
+ my $orig = shift;
+ my $self = shift;
+ my @result = grep { $_->sub_class eq 'segment' } $self->$orig( @_ );
+ return @result;
+};
+
+# Wrapper around merge_nodes
sub merge_readings {
my $self = shift;
return $self->graph->merge_nodes( @_ );
}
+# Extra graph-alike utility
+sub has_path {
+ my( $self, $source, $target, $label ) = @_;
+ my @paths = $source->edges_to( $target );
+ my @relevant = grep { $_->label eq $label } @paths;
+ return scalar @relevant;
+}
+
+## Dealing with groups of readings, i.e. segments.
+
+sub add_segment {
+ my( $self, @items ) = @_;
+ my $segment = Text::Tradition::Collation::Segment->new( 'members' => \@items );
+ return $segment;
+}
+
+## Dealing with relationships between readings. This is a different
+## sort of graph edge. Return a success/failure value and a list of
+## node pairs that have been linked.
+
+sub add_relationship {
+ my( $self, $source, $target, $options ) = @_;
+
+ # Make sure there is not another relationship between these two
+ # readings or segments already
+ $source = $self->reading( $source )
+ unless ref( $source ) && $source->isa( 'Graph::Easy::Node' );
+ $target = $self->reading( $target )
+ unless ref( $target ) && $target->isa( 'Graph::Easy::Node' );
+ foreach my $rel ( $source->edges_to( $target ), $target->edges_to( $source ) ) {
+ if( $rel->class eq 'edge.relationship' ) {
+ return ( undef, "Relationship already exists between these readings" );
+ } else {
+ return ( undef, "There is a witness path between these readings" );
+ }
+ }
+
+ if( $source->has_position && $target->has_position ) {
+ unless( grep { $_ eq $target } $self->same_position_as( $source ) ) {
+ return( undef, "Cannot set relationship at different positions" );
+ }
+ }
+
+ my @joined = ( [ $source->name, $target->name ] ); # Keep track of the nodes we join.
+
+ $options->{'this_relation'} = [ $source, $target ];
+ my $rel;
+ eval { $rel = Text::Tradition::Collation::Relationship->new( %$options ) };
+ if( $@ ) {
+ return ( undef, $@ );
+ }
+ $self->graph->add_edge( $source, $target, $rel );
+ if( $options->{'global'} ) {
+ # Look for all readings with the source label, and if there are
+ # colocated readings with the target label, join them too.
+ foreach my $r ( grep { $_->label eq $source->label } $self->readings() ) {
+ next if $r->name eq $source->name;
+ my @colocated = grep { $_->label eq $target->label }
+ $self->same_position_as( $r );
+ if( @colocated ) {
+ warn "Multiple readings with same label at same position!"
+ if @colocated > 1;
+ my $colo = $colocated[0];
+ next if $colo->edges_to( $r ) || $r->edges_to( $colo );
+ $options->{'primary_relation'} = $options->{'this_relation'};
+ $options->{'this_relation'} = [ $r, $colocated[0] ];
+ my $dup_rel = Text::Tradition::Collation::Relationship->new( %$options );
+ $self->graph->add_edge( $r, $colocated[0], $dup_rel );
+ push( @joined, [ $r->name, $colocated[0]->name ] );
+ }
+ }
+ }
+ return( 1, @joined );
+}
+
=head2 Output method(s)
=over
my( $self, $recalc ) = @_;
return $self->svg if $self->has_svg;
- $self->_save_graphviz( $self->graph->as_graphviz() )
- unless( $self->has_graphviz && !$recalc );
+ $self->collapse_graph_paths();
my @cmd = qw/dot -Tsvg/;
my( $svg, $err );
- my $in = $self->graphviz;
+ my $in = $self->as_dot();
run( \@cmd, \$in, ">", binary(), \$svg );
- $self->{'svg'} = $svg;
+ $self->_save_svg( $svg );
+ $self->expand_graph_paths();
return $svg;
}
+=item B<as_dot>
+
+print $graph->as_dot( $view, $recalculate );
+
+Returns a string that is the collation graph expressed in dot
+(i.e. GraphViz) format. The 'view' argument determines what kind of
+graph is produced.
+ * 'path': a graph of witness paths through the collation (DEFAULT)
+ * 'relationship': a graph of how collation readings relate to
+ each other
+
+=cut
+
+sub as_dot {
+ my( $self, $view ) = @_;
+ $view = 'path' unless $view;
+ # TODO consider making some of these things configurable
+ my $dot = sprintf( "digraph %s {\n", $self->tradition->name );
+ $dot .= "\tedge [ arrowhead=open ];\n";
+ $dot .= "\tgraph [ rankdir=LR ];\n";
+ $dot .= sprintf( "\tnode [ fontsize=%d, fillcolor=%s, style=%s, shape=%s ];\n",
+ 11, "white", "filled", $self->graph->get_attribute( 'node', 'shape' ) );
+
+ foreach my $reading ( $self->readings ) {
+ # Need not output nodes without separate labels
+ next if $reading->name eq $reading->label;
+ # TODO output readings or segments, but not both
+ next if $reading->class eq 'node.segment';
+ $dot .= sprintf( "\t\"%s\" [ label=\"%s\" ]\n", $reading->name, $reading->label );
+ }
+
+ my @edges = $view eq 'relationship' ? $self->relationships : $self->paths;
+ foreach my $edge ( @edges ) {
+ my %variables = ( 'color' => '#000000',
+ 'fontcolor' => '#000000',
+ 'label' => $edge->label,
+ );
+ my $varopts = join( ', ', map { $_.'="'.$variables{$_}.'"' } sort keys %variables );
+ $dot .= sprintf( "\t\"%s\" -> \"%s\" [ %s ]\n",
+ $edge->from->name, $edge->to->name, $varopts );
+ }
+ $dot .= "}\n";
+ return $dot;
+}
+
=item B<as_graphml>
print $graph->as_graphml( $recalculate )
$root->setNamespace( $xsi_ns, 'xsi', 0 );
$root->setAttributeNS( $xsi_ns, 'schemaLocation', $graphml_schema );
+ # TODO Add some global graph data
+
# Add the data keys for nodes
- my @node_data = ( 'name', 'token', 'identical', 'position' );
- foreach my $ndi ( 0 .. $#node_data ) {
+ my %node_data_keys;
+ my $ndi = 0;
+ foreach my $datum ( qw/ name reading identical position class / ) {
+ $node_data_keys{$datum} = 'dn'.$ndi++;
my $key = $root->addNewChild( $graphml_ns, 'key' );
- $key->setAttribute( 'attr.name', $node_data[$ndi] );
+ $key->setAttribute( 'attr.name', $datum );
$key->setAttribute( 'attr.type', 'string' );
$key->setAttribute( 'for', 'node' );
- $key->setAttribute( 'id', 'd'.$ndi );
+ $key->setAttribute( 'id', $node_data_keys{$datum} );
}
- # Add the data keys for edges
- my %wit_hash;
- my $wit_ctr = 0;
- foreach my $wit ( $self->getWitnessList ) {
- my $wit_key = 'w' . $wit_ctr++;
- $wit_hash{$wit} = $wit_key;
+ # Add the data keys for edges, i.e. witnesses
+ my $edi = 0;
+ my %edge_data_keys;
+ foreach my $edge_key( qw/ witness_main witness_ante_corr relationship class / ) {
+ $edge_data_keys{$edge_key} = 'de'.$edi++;
my $key = $root->addNewChild( $graphml_ns, 'key' );
- $key->setAttribute( 'attr.name', $wit );
+ $key->setAttribute( 'attr.name', $edge_key );
$key->setAttribute( 'attr.type', 'string' );
$key->setAttribute( 'for', 'edge' );
- $key->setAttribute( 'id', $wit_key );
+ $key->setAttribute( 'id', $edge_data_keys{$edge_key} );
}
-
+
# Add the graph, its nodes, and its edges
my $graph = $root->addNewChild( $graphml_ns, 'graph' );
$graph->setAttribute( 'edgedefault', 'directed' );
$graph->setAttribute( 'id', 'g0' ); # TODO make this meaningful
$graph->setAttribute( 'parse.edgeids', 'canonical' );
- $graph->setAttribute( 'parse.edges', $self->edges() );
+ $graph->setAttribute( 'parse.edges', scalar($self->paths) );
$graph->setAttribute( 'parse.nodeids', 'canonical' );
- $graph->setAttribute( 'parse.nodes', $self->nodes() );
+ $graph->setAttribute( 'parse.nodes', scalar($self->readings) );
$graph->setAttribute( 'parse.order', 'nodesfirst' );
my $node_ctr = 0;
my %node_hash;
- foreach my $n ( $self->readings ) {
- my %this_node_data = ();
- foreach my $ndi ( 0 .. $#node_data ) {
- my $value;
- $this_node_data{'d'.$ndi} = $n->name if $node_data[$ndi] eq 'name';
- $this_node_data{'d'.$ndi} = $n->label
- if $node_data[$ndi] eq 'token';
- $this_node_data{'d'.$ndi} = $n->primary->name if $n->has_primary;
- $this_node_data{'d'.$ndi} =
- $self->{'positions'}->node_position( $n )
- if $node_data[$ndi] eq 'position';
- }
+ # Add our readings to the graph
+ foreach my $n ( sort { $a->name cmp $b->name } $self->readings ) {
my $node_el = $graph->addNewChild( $graphml_ns, 'node' );
my $node_xmlid = 'n' . $node_ctr++;
$node_hash{ $n->name } = $node_xmlid;
$node_el->setAttribute( 'id', $node_xmlid );
-
- foreach my $dk ( keys %this_node_data ) {
- my $d_el = $node_el->addNewChild( $graphml_ns, 'data' );
- $d_el->setAttribute( 'key', $dk );
- $d_el->appendTextChild( $this_node_data{$dk} );
- }
+ _add_graphml_data( $node_el, $node_data_keys{'name'}, $n->name );
+ _add_graphml_data( $node_el, $node_data_keys{'reading'}, $n->label );
+ _add_graphml_data( $node_el, $node_data_keys{'position'}, $n->position->reference )
+ if $n->has_position;
+ _add_graphml_data( $node_el, $node_data_keys{'class'}, $n->sub_class );
+ _add_graphml_data( $node_el, $node_data_keys{'identical'}, $n->primary->name )
+ if $n->has_primary;
+ }
+
+ # Add any segments we have
+ foreach my $n ( sort { $a->name cmp $b->name } $self->segments ) {
+ my $node_el = $graph->addNewChild( $graphml_ns, 'node' );
+ my $node_xmlid = 'n' . $node_ctr++;
+ $node_hash{ $n->name } = $node_xmlid;
+ $node_el->setAttribute( 'id', $node_xmlid );
+ _add_graphml_data( $node_el, $node_data_keys{'class'}, $n->sub_class );
+ _add_graphml_data( $node_el, $node_data_keys{'name'}, $n->name );
}
- foreach my $e ( $self->edges() ) {
- my( $name, $from, $to ) = ( $e->name,
- $node_hash{ $e->from()->name() },
- $node_hash{ $e->to()->name() } );
+ # Add the path, relationship, and segment edges
+ my $edge_ctr = 0;
+ foreach my $e ( sort { $a->from->name cmp $b->from->name } $self->graph->edges() ) {
+ my( $name, $from, $to ) = ( 'e'.$edge_ctr++,
+ $node_hash{ $e->from->name() },
+ $node_hash{ $e->to->name() } );
my $edge_el = $graph->addNewChild( $graphml_ns, 'edge' );
$edge_el->setAttribute( 'source', $from );
$edge_el->setAttribute( 'target', $to );
$edge_el->setAttribute( 'id', $name );
- # TODO Got to add the witnesses
+ # Add the edge class
+ _add_graphml_data( $edge_el, $edge_data_keys{'class'}, $e->sub_class );
+ if( $e->sub_class eq 'path' ) {
+ # It's a witness path, so add the witness
+ my $base = $e->label;
+ my $key = $edge_data_keys{'witness_main'};
+ # TODO kind of hacky
+ if( $e->label =~ /^(.*?)\s+(\(a\.c\.\))$/ ) {
+ $base = $1;
+ $key = $edge_data_keys{'witness_ante_corr'};
+ }
+ _add_graphml_data( $edge_el, $key, $base );
+ } elsif( $e->sub_class eq 'relationship' ) {
+ # It's a relationship
+ _add_graphml_data( $edge_el, $edge_data_keys{'relationship'}, $e->label );
+ } # else a segment, nothing to record but source, target, class
}
# Return the thing
- $self->_save_graphml( $graphml );
- return $graphml;
+ $self->_save_graphml( $graphml->toString(1) );
+ return $graphml->toString(1);
+}
+
+sub _add_graphml_data {
+ my( $el, $key, $value ) = @_;
+ my $data_el = $el->addNewChild( $el->namespaceURI, 'data' );
+ return unless defined $value;
+ $data_el->setAttribute( 'key', $key );
+ $data_el->appendText( $value );
+}
+
+sub collapse_graph_paths {
+ my $self = shift;
+ # Our collation graph has an path per witness. This is great for
+ # calculation purposes, but terrible for display. Thus we want to
+ # display only one path between any two nodes.
+
+ return if $self->collapsed;
+
+ print STDERR "Collapsing witness paths in graph...\n";
+
+ # Don't list out every witness if we have more than half to list.
+ my $majority = int( scalar( @{$self->tradition->witnesses} ) / 2 ) + 1;
+ # But don't compress if there are only a few witnesses.
+ $majority = 4 if $majority < 4;
+ foreach my $node ( $self->readings ) {
+ my $newlabels = {};
+ # We will visit each node, so we only look ahead.
+ foreach my $edge ( $node->outgoing() ) {
+ next unless $edge->class eq 'edge.path';
+ add_hash_entry( $newlabels, $edge->to->name, $edge->name );
+ $self->del_path( $edge );
+ }
+
+ foreach my $newdest ( keys %$newlabels ) {
+ my $label;
+ my @compressed_wits = ();
+ if( @{$newlabels->{$newdest}} < $majority ) {
+ $label = join( ', ', sort( @{$newlabels->{$newdest}} ) );
+ } else {
+ ## TODO FIX THIS HACK
+ my @aclabels;
+ foreach my $wit ( @{$newlabels->{$newdest}} ) {
+ if( $wit =~ /^(.*?)(\s*\(?a\.\s*c\.\)?)$/ ) {
+ push( @aclabels, $wit );
+ } else {
+ push( @compressed_wits, $wit );
+ }
+ }
+ $label = join( ', ', 'majority', sort( @aclabels ) );
+ }
+
+ my $newpath =
+ $self->add_path( $node, $self->reading( $newdest ), $label );
+ if( @compressed_wits ) {
+ $newpath->hidden_witnesses( \@compressed_wits );
+ }
+ }
+ }
+
+ $self->collapsed( 1 );
+}
+
+sub expand_graph_paths {
+ my $self = shift;
+ # Our collation graph has only one path between any two nodes.
+ # This is great for display, but not so great for analysis.
+ # Expand this so that each witness has its own path between any
+ # two reading nodes.
+ return unless $self->collapsed;
+
+ print STDERR "Expanding witness paths in graph...\n";
+ foreach my $path( $self->paths ) {
+ my $from = $path->from;
+ my $to = $path->to;
+ my @wits = split( /, /, $path->label );
+ if( $path->has_hidden_witnesses ) {
+ push( @wits, @{$path->hidden_witnesses} );
+ }
+ $self->del_path( $path );
+ foreach ( @wits ) {
+ $self->add_path( $from, $to, $_ );
+ }
+ }
+ $self->collapsed( 0 );
}
=back
+=head2 Navigation methods
+
+=over
+
=item B<start>
my $beginning = $collation->start();
return $self->reading('#START#');
}
+=item B<reading_sequence>
+
+my @readings = $graph->reading_sequence( $first, $last, $path[, $alt_path] );
+
+Returns the ordered list of readings, starting with $first and ending
+with $last, along the given witness path. If no path is specified,
+assume that the path is that of the base text (if any.)
+
+=cut
+
+sub reading_sequence {
+ my( $self, $start, $end, $witness, $backup ) = @_;
+
+ $witness = $self->baselabel unless $witness;
+ my @readings = ( $start );
+ my %seen;
+ my $n = $start;
+ while( $n && $n ne $end ) {
+ if( exists( $seen{$n->name()} ) ) {
+ warn "Detected loop at " . $n->name();
+ last;
+ }
+ $seen{$n->name()} = 1;
+
+ my $next = $self->next_reading( $n, $witness, $backup );
+ warn "Did not find any path for $witness from reading " . $n->name
+ unless $next;
+ push( @readings, $next );
+ $n = $next;
+ }
+ # Check that the last reading is our end reading.
+ my $last = $readings[$#readings];
+ warn "Last reading found from " . $start->label() .
+ " for witness $witness is not the end!"
+ unless $last eq $end;
+
+ return @readings;
+}
+
=item B<next_reading>
my $next_reading = $graph->next_reading( $reading, $witpath );
Returns the reading that follows the given reading along the given witness
-path. TODO These are badly named.
+path.
=cut
sub next_reading {
- # Return the successor via the corresponding edge.
+ # Return the successor via the corresponding path.
my $self = shift;
return $self->_find_linked_reading( 'next', @_ );
}
my $prior_reading = $graph->prior_reading( $reading, $witpath );
Returns the reading that precedes the given reading along the given witness
-path. TODO These are badly named.
+path.
=cut
sub prior_reading {
- # Return the predecessor via the corresponding edge.
+ # Return the predecessor via the corresponding path.
my $self = shift;
return $self->_find_linked_reading( 'prior', @_ );
}
sub _find_linked_reading {
- my( $self, $direction, $node, $edge ) = @_;
- $edge = 'base text' unless $edge;
- my @linked_edges = $direction eq 'next'
+ my( $self, $direction, $node, $path, $alt_path ) = @_;
+ my @linked_paths = $direction eq 'next'
? $node->outgoing() : $node->incoming();
- return undef unless scalar( @linked_edges );
+ return undef unless scalar( @linked_paths );
- # We have to find the linked edge that contains all of the
- # witnesses supplied in $edge.
- my @edge_wits = $self->witnesses_of_label( $edge );
- foreach my $le ( @linked_edges ) {
- my @le_wits = $self->witnesses_of_label( $le->name );
- if( _is_within( \@edge_wits, \@le_wits ) ) {
- # This is the right edge.
- return $direction eq 'next' ? $le->to() : $le->from();
+ # We have to find the linked path that contains all of the
+ # witnesses supplied in $path.
+ my( @path_wits, @alt_path_wits );
+ @path_wits = $self->witnesses_of_label( $path ) if $path;
+ @alt_path_wits = $self->witnesses_of_label( $alt_path ) if $alt_path;
+ my $base_le;
+ my $alt_le;
+ foreach my $le ( @linked_paths ) {
+ if( $le->name eq $self->baselabel ) {
+ $base_le = $le;
+ } else {
+ my @le_wits = $self->witnesses_of_label( $le->name );
+ if( _is_within( \@path_wits, \@le_wits ) ) {
+ # This is the right path.
+ return $direction eq 'next' ? $le->to() : $le->from();
+ } elsif( _is_within( \@alt_path_wits, \@le_wits ) ) {
+ $alt_le = $le;
+ }
}
}
+ # Got this far? Return the alternate path if it exists.
+ return $direction eq 'next' ? $alt_le->to() : $alt_le->from()
+ if $alt_le;
+
+ # Got this far? Return the base path if it exists.
+ return $direction eq 'next' ? $base_le->to() : $base_le->from()
+ if $base_le;
+
+ # Got this far? We have no appropriate path.
warn "Could not find $direction node from " . $node->label
- . " along edge $edge";
+ . " along path $path";
return undef;
}
# Some set logic.
sub _is_within {
my( $set1, $set2 ) = @_;
- my $ret = 1;
+ my $ret = @$set1; # will be 0, i.e. false, if set1 is empty
foreach my $el ( @$set1 ) {
$ret = 0 unless grep { /^\Q$el\E$/ } @$set2;
}
return $ret;
}
+
+## INITIALIZATION METHODS - for use by parsers
# Walk the paths for each witness in the graph, and return the nodes
-# that the graph has in common.
+# that the graph has in common. If $using_base is true, some
+# different logic is needed.
sub walk_witness_paths {
my( $self, $end ) = @_;
# TODO This method is going to fall down if we have a very gappy
# text in the collation.
my $paths = {};
- my @common_nodes;
+ my @common_readings;
foreach my $wit ( @{$self->tradition->witnesses} ) {
my $curr_reading = $self->start;
- my @wit_path = ( $curr_reading );
- my %seen_readings;
- # TODO Detect loops at some point
- while( $curr_reading->name ne $end->name ) {
- if( $seen_readings{$curr_reading->name} ) {
- warn "Detected loop walking path for witness " . $wit->sigil
- . " at reading " . $curr_reading->name;
- last;
- }
- my $next_reading = $self->next_reading( $curr_reading,
- $wit->sigil );
- push( @wit_path, $next_reading );
- $seen_readings{$curr_reading->name} = 1;
- $curr_reading = $next_reading;
- }
+ my @wit_path = $self->reading_sequence( $self->start, $end,
+ $wit->sigil );
$wit->path( \@wit_path );
- if( @common_nodes ) {
- my @cn;
- foreach my $n ( @wit_path ) {
- push( @cn, $n ) if grep { $_ eq $n } @common_nodes;
- }
- @common_nodes = ();
- push( @common_nodes, @cn );
- } else {
- push( @common_nodes, @wit_path );
- }
+
+ # Detect the common readings.
+ @common_readings = _find_common( \@common_readings, \@wit_path );
}
# Mark all the nodes as either common or not.
- foreach my $cn ( @common_nodes ) {
- print STDERR "Setting " . $cn->name . " as common node\n";
+ foreach my $cn ( @common_readings ) {
+ print STDERR "Setting " . $cn->name . " / " . $cn->label
+ . " as common node\n";
$cn->make_common;
}
foreach my $n ( $self->readings() ) {
$n->make_variant unless $n->is_common;
}
+ # Return an array of the common nodes in order.
+ return @common_readings;
+}
+
+sub _find_common {
+ my( $common_readings, $new_path ) = @_;
+ my @cr;
+ if( @$common_readings ) {
+ foreach my $n ( @$new_path ) {
+ push( @cr, $n ) if grep { $_ eq $n } @$common_readings;
+ }
+ } else {
+ push( @cr, @$new_path );
+ }
+ return @cr;
+}
+
+sub _remove_common {
+ my( $common_readings, $divergence ) = @_;
+ my @cr;
+ my %diverged;
+ map { $diverged{$_->name} = 1 } @$divergence;
+ foreach( @$common_readings ) {
+ push( @cr, $_ ) unless $diverged{$_->name};
+ }
+ return @cr;
+}
+
+
+# An alternative to walk_witness_paths, for use when a collation is
+# constructed from a base text and an apparatus. We have the
+# sequences of readings and just need to add path edges.
+
+sub make_witness_paths {
+ my( $self ) = @_;
+
+ my @common_readings;
+ foreach my $wit ( @{$self->tradition->witnesses} ) {
+ print STDERR "Making path for " . $wit->sigil . "\n";
+ $self->make_witness_path( $wit );
+ @common_readings = _find_common( \@common_readings, $wit->path );
+ @common_readings = _find_common( \@common_readings, $wit->uncorrected_path );
+ }
+ map { $_->make_common } @common_readings;
+ return @common_readings;
+}
+
+sub make_witness_path {
+ my( $self, $wit ) = @_;
+ my @chain = @{$wit->path};
+ my $sig = $wit->sigil;
+ foreach my $idx ( 0 .. $#chain-1 ) {
+ $self->add_path( $chain[$idx], $chain[$idx+1], $sig );
+ }
+ @chain = @{$wit->uncorrected_path};
+ foreach my $idx( 0 .. $#chain-1 ) {
+ my $source = $chain[$idx];
+ my $target = $chain[$idx+1];
+ $self->add_path( $source, $target, $sig.$self->ac_label )
+ unless $self->has_path( $source, $target, $sig );
+ }
}
sub common_readings {
my $self = shift;
my @common = grep { $_->is_common } $self->readings();
- return @common;
+ return sort { $a->position->cmp_with( $b->position ) } @common;
}
# Calculate the relative positions of nodes in the graph, if they
# were not given to us.
sub calculate_positions {
- my $self = shift;
+ my( $self, @ordered_common ) = @_;
- # We have to calculate the position identifiers for each word,
- # keyed on the common nodes. This will be 'fun'. The end result
- # is a hash per witness, whose key is the word node and whose
- # value is its position in the text. Common nodes are always N,1
- # so have identical positions in each text.
- my @common = $self->common_readings();
+ # First assign positions to all the common nodes.
+ my $l = 1;
+ foreach my $oc ( @ordered_common ) {
+ $oc->position( $l++, 1 );
+ }
- my $node_pos = {};
- foreach my $wit ( @{$self->tradition->witnesses} ) {
- # First we walk each path, making a matrix for each witness that
- # corresponds to its eventual position identifier. Common nodes
- # always start a new row, and are thus always in the first column.
-
- my $wit_matrix = [];
- my $cn = 0; # We should hit the common readings in order.
- my $row = [];
- foreach my $wn ( @{$wit->path} ) {
- if( $wn eq $common[$cn] ) {
- # Set up to look for the next common node, and
- # start a new row of words.
- $cn++;
- push( @$wit_matrix, $row ) if scalar( @$row );
- $row = [];
+ if( $self->linear ) {
+ # For the space between each common node, we have to find all the chains
+ # from all the witnesses. The longest chain gives us our max, and the
+ # others get min/max ranges to fit.
+ my $first = shift @ordered_common;
+ while( @ordered_common ) {
+ my %paths;
+ my $next = shift @ordered_common;
+ my $longest = 0;
+ foreach my $wit ( @{$self->tradition->witnesses} ) {
+ # Key to the path is not important; we just have to get
+ # all unique paths.
+ my $length = $self->_track_paths( \%paths, $first, $next, $wit->sigil );
+ $longest = $length unless $longest > $length;
+ if( $wit->has_ante_corr ) {
+ my $length = $self->_track_paths( \%paths, $first, $next,
+ $wit->sigil.$self->ac_label, $wit->sigil );
+ $longest = $length unless $longest > $length;
+ }
+ }
+
+ # Transform the path values from unique strings to arrays.
+ my @all_paths;
+ foreach my $k ( keys %paths ) {
+ my @v = split( /\s+/, $k );
+ push( @all_paths, \@v );
}
- push( @$row, $wn );
+ @all_paths = sort { scalar @$b <=> scalar @$a } @all_paths;
+
+ # Now %paths has all the unique paths, and we know how long the
+ # longest of these is. Assign positions, starting with the
+ # longest. All non-common positions start at 2.
+ foreach my $path ( @all_paths ) {
+ # Initially each element has a minimum position of 2
+ # plus its position in the array (1 is the common
+ # node), and a max position of the longest array
+ # length minus its position in the array.
+ my $range = $longest - scalar @$path;
+ my $min = 2;
+ foreach my $i ( 0 .. $#{$path} ) {
+ my $rdg = $self->reading( $path->[$i] );
+ if( $rdg->has_position ) {
+ # This reading has already had a more specific
+ # position set, so we need to take that into
+ # account when calculating the min and max for
+ # the next reading.
+ my $rangeminus = $rdg->position->min - $min;
+ $min = $rdg->position->min + 1;
+ $range = $range - $rangeminus;
+ if( $range < 0 ) {
+ print STDERR "Negative range for position! " . $rdg->name . "\n"; # May remove this warning
+ $range = 0;
+ }
+ } else {
+ $rdg->position( $first->position->common, $min, $min+$range );
+ $min++;
+ $longest = $min+$range-2 unless $longest+2 > $min+$range; # min starts at 2 but longest assumes 0 start
+ }
+ }
+ }
+ # Now go through again and make sure the positions are
+ # monotonic. Do this until they are.
+ my $monotonic = 0;
+ my $counter = 0;
+ until( $monotonic ) {
+ $monotonic = 1;
+ $counter++;
+ foreach my $path ( @all_paths ) {
+ foreach my $i ( 0 .. $#{$path} ) {
+ my $rdg = $self->reading( $path->[$i] );
+ my $prior = $self->reading( $path->[$i-1] ) if $i > 0;
+ my $next = $self->reading( $path->[$i+1] ) if $i < $#{$path};
+ if( $prior && $rdg->position->min <= $prior->position->min ) {
+ $monotonic = 0;
+ $rdg->position->min( $prior->position->min + 1 );
+ }
+ if( $next && $rdg->position->max >= $next->position->max ) {
+ $monotonic = 0;
+ if( $next->position->max - 1 >= $rdg->position->min ) {
+ # If moving rdg/max down would not send it below
+ # rdg/min, do that.
+ $rdg->position->max( $next->position->max - 1 );
+ } else {
+ # Otherwise increase next/max.
+ $next->position->max( $rdg->position->max + 1 );
+ # ...min will be fixed on the next pass.
+ }
+ }
+ }
+ }
+ if( $counter > $#all_paths + 1 && !$monotonic ) {
+ # We risk an infinite loop. Get out of here.
+ warn "Still not monotonic after $counter passes at common point "
+ . $first->position->common;
+ last;
+ }
+ }
+ print STDERR "Took $counter passes for monotonicity at " . $first->position->common. "\n"
+ if $counter > 1;
+
+ $first = $next;
}
- push( @$wit_matrix, $row ); # Push the last row onto the matrix
-
- # Now we have a matrix per witness, so that each row in the
- # matrix begins with a common node, and continues with all the
- # variant words that appear in the witness. We turn this into
- # real positions in row,cell format. But we need some
- # trickery in order to make sure that each node gets assigned
- # to only one position.
-
- foreach my $li ( 1..scalar(@$wit_matrix) ) {
- foreach my $di ( 1..scalar(@{$wit_matrix->[$li-1]}) ) {
- my $reading = $wit_matrix->[$li-1]->[$di-1];
- my $position = "$li,$di";
- # If we have seen this node before, we need to compare
- # its position with what went before.
- unless( $reading->has_position &&
- _cmp_position( $position, $reading->position ) < 1 ) {
- # The new position ID replaces the old one.
- $reading->position( $position );
- } # otherwise, the old position needs to stay.
+
+ } else {
+
+ # Non-linear positions are pretty much impossible to pin down.
+ # Any reading might appear anywhere in the graph. I guess we
+ # can do positions where there aren't transpositions...
+
+ }
+ $self->init_lemmata();
+}
+
+# Helper function for the guts of calculate_positions.
+sub _track_paths {
+ my $self = shift;
+ my $track_hash = shift;
+ # Args are first, last, wit, backup
+ my @path = $self->reading_sequence( @_ );
+ # Top and tail the array
+ shift @path;
+ pop @path;
+ $track_hash->{join( ' ', map { $_->name } @path )} = $_[2]
+ if @path;
+ return @path;
+}
+
+sub possible_positions {
+ my $self = shift;
+ my @answer;
+ my %positions = ();
+ foreach my $r ( $self->readings ) {
+ next unless $r->has_position;
+ $positions{$r->position->maxref} = 1;
+ }
+ @answer = keys %positions;
+ return @answer;
+}
+
+# TODO think about indexing this.
+sub readings_at_position {
+ my( $self, $position, $strict ) = @_;
+ unless( ref( $position ) eq 'Text::Tradition::Collation::Position' ) {
+ $position = Text::Tradition::Collation::Position->new( $position );
+ }
+ my @answer;
+ foreach my $r ( $self->readings ) {
+ push( @answer, $r ) if $r->is_at_position( $position, $strict );
+ }
+ return @answer;
+}
+
+## Lemmatizer functions
+
+sub init_lemmata {
+ my $self = shift;
+
+ foreach my $position ( $self->possible_positions ) {
+ $self->lemmata->{$position} = undef;
+ }
+
+ foreach my $cr ( $self->common_readings ) {
+ $self->lemmata->{$cr->position->maxref} = $cr->name;
+ }
+}
+
+=item B<lemma_readings>
+
+my @state = $graph->lemma_readings( @readings_delemmatized );
+
+Takes a list of readings that have just been delemmatized, and returns
+a set of tuples of the form ['reading', 'state'] that indicates what
+changes need to be made to the graph.
+
+=over
+
+=item *
+
+A state of 1 means 'lemmatize this reading'
+
+=item *
+
+A state of 0 means 'delemmatize this reading'
+
+=item *
+
+A state of undef means 'an ellipsis belongs in the text here because
+no decision has been made / an earlier decision was backed out'
+
+=back
+
+=cut
+
+sub lemma_readings {
+ my( $self, @toggled_off_nodes ) = @_;
+
+ # First get the positions of those nodes which have been
+ # toggled off.
+ my $positions_off = {};
+ map { $positions_off->{ $_->position->reference } = $_->name }
+ @toggled_off_nodes;
+
+ # Now for each position, we have to see if a node is on, and we
+ # have to see if a node has been turned off. The lemmata hash
+ # should contain fixed positions, range positions whose node was
+ # just turned off, and range positions whose node is on.
+ my @answer;
+ my %fixed_positions;
+ # TODO One of these is probably redundant.
+ map { $fixed_positions{$_} = 0 } keys %{$self->lemmata};
+ map { $fixed_positions{$_} = 0 } keys %{$positions_off};
+ map { $fixed_positions{$_} = 1 } $self->possible_positions;
+ foreach my $pos ( sort { Text::Tradition::Collation::Position::str_cmp( $a, $b ) } keys %fixed_positions ) {
+ # Find the state of this position. If there is an active node,
+ # its name will be the state; otherwise the state will be 0
+ # (nothing at this position) or undef (ellipsis at this position)
+ my $active = undef;
+ $active = $self->lemmata->{$pos} if exists $self->lemmata->{$pos};
+
+ # Is there a formerly active node that was toggled off?
+ if( exists( $positions_off->{$pos} ) ) {
+ my $off_node = $positions_off->{$pos};
+ if( $active && $active ne $off_node) {
+ push( @answer, [ $off_node, 0 ], [ $active, 1 ] );
+ } else {
+ unless( $fixed_positions{$pos} ) {
+ $active = 0;
+ delete $self->lemmata->{$pos};
+ }
+ push( @answer, [ $off_node, $active ] );
}
+
+ # No formerly active node, so we just see if there is a currently
+ # active one.
+ } elsif( $active ) {
+ # Push the active node, whatever it is.
+ push( @answer, [ $active, 1 ] );
+ } else {
+ # Push the state that is there. Arbitrarily use the first node
+ # at that position.
+ my @pos_nodes = $self->readings_at_position( $pos );
+ push( @answer, [ $pos_nodes[0]->name, $self->lemmata->{$pos} ] );
+ delete $self->lemmata->{$pos} unless $fixed_positions{$pos};
}
}
+
+ return @answer;
}
-sub _cmp_position {
- my( $a, $b ) = @_;
- my @pos_a = split(/,/, $a );
- my @pos_b = split(/,/, $b );
+=item B<toggle_reading>
+
+my @readings_delemmatized = $graph->toggle_reading( $reading_name );
+
+Takes a reading node name, and either lemmatizes or de-lemmatizes
+it. Returns a list of all readings that are de-lemmatized as a result
+of the toggle.
+
+=cut
+
+sub toggle_reading {
+ my( $self, $rname ) = @_;
+
+ return unless $rname;
+ my $reading = $self->reading( $rname );
+ if( !$reading || $reading->is_common() ) {
+ # Do nothing, it's a common node.
+ return;
+ }
+
+ my $pos = $reading->position;
+ my $fixed = $reading->position->fixed;
+ my $old_state = $self->lemmata->{$pos->reference};
+
+ my @readings_off;
+ if( $old_state && $old_state eq $rname ) {
+ # Turn off the node. We turn on no others by default.
+ push( @readings_off, $reading );
+ } else {
+ # Turn on the node.
+ $self->lemmata->{$pos->reference} = $rname;
+ # Any other 'on' readings in the same position should be off
+ # if we have a fixed position.
+ push( @readings_off, $self->same_position_as( $reading, 1 ) )
+ if $pos->fixed;
+ # Any node that is an identical transposed one should be off.
+ push( @readings_off, $reading->identical_readings );
+ }
+ @readings_off = unique_list( @readings_off );
+
+ # Turn off the readings that need to be turned off.
+ my @readings_delemmatized;
+ foreach my $n ( @readings_off ) {
+ my $npos = $n->position;
+ my $state = undef;
+ $state = $self->lemmata->{$npos->reference}
+ if defined $self->lemmata->{$npos->reference};
+ if( $state && $state eq $n->name ) {
+ # this reading is still on, so turn it off
+ push( @readings_delemmatized, $n );
+ my $new_state = undef;
+ if( $npos->fixed && $n eq $reading ) {
+ # This is the reading that was clicked, so if there are no
+ # other readings there and this is a fixed position, turn off
+ # the position. In all other cases, restore the ellipsis.
+ my @other_n = $self->same_position_as( $n ); # TODO do we need strict?
+ $new_state = 0 unless @other_n;
+ }
+ $self->lemmata->{$npos->reference} = $new_state;
+ } elsif( $old_state && $old_state eq $n->name ) {
+ # another reading has already been turned on here
+ push( @readings_delemmatized, $n );
+ } # else some other reading was on anyway, so pass.
+ }
+ return @readings_delemmatized;
+}
- my $big_cmp = $pos_a[0] <=> $pos_b[0];
- return $big_cmp if $big_cmp;
- # else
- return $pos_a[1] <=> $pos_b[1];
+sub same_position_as {
+ my( $self, $reading, $strict ) = @_;
+ my $pos = $reading->position;
+ my %onpath = ( $reading->name => 1 );
+ # TODO This might not always be sufficient. We really want to
+ # exclude all readings on this one's path between its two
+ # common points.
+ map { $onpath{$_->name} = 1 } $reading->neighbor_readings;
+ my @same = grep { !$onpath{$_->name} }
+ $self->readings_at_position( $reading->position, $strict );
+ return @same;
}
-
+
# Return the string that joins together a list of witnesses for
# display on a single path.
sub path_label {
}
sub witnesses_of_label {
- my $self = shift;
+ my( $self, $label ) = @_;
my $regex = $self->wit_list_separator;
- return split( /^\Q$regex\E$/, @_ );
+ my @answer = split( /\Q$regex\E/, $label );
+ return @answer;
}
+sub unique_list {
+ my( @list ) = @_;
+ my %h;
+ map { $h{$_->name} = $_ } @list;
+ return values( %h );
+}
+
+sub add_hash_entry {
+ my( $hash, $key, $entry ) = @_;
+ if( exists $hash->{$key} ) {
+ push( @{$hash->{$key}}, $entry );
+ } else {
+ $hash->{$key} = [ $entry ];
+ }
+}
+
no Moose;
__PACKAGE__->meta->make_immutable;