my $cxfile = 't/data/Collatex-16.xml';
my $t = Text::Tradition->new(
- 'name' => 'inline',
- 'input' => 'CollateX',
- 'file' => $cxfile,
- );
+ 'name' => 'inline',
+ 'input' => 'CollateX',
+ 'file' => $cxfile,
+ );
my $c = $t->collation;
my @v1 = $c->add_relationship( 'n21', 'n22', { 'type' => 'lexical' } );
=begin testing
+use Test::Warn;
use Text::Tradition;
use TryCatch;
-my $t1 = Text::Tradition->new( 'input' => 'Self', 'file' => 't/data/legendfrag.xml' );
+my $t1;
+warning_is {
+ $t1 = Text::Tradition->new( 'input' => 'Self', 'file' => 't/data/legendfrag.xml' );
+} 'DROPPING r14.2 -> r8.1: Cannot set relationship on a meta reading',
+ "Got expected relationship drop warning on parse";
+
# Test 1.1: try to equate nodes that are prevented with an intermediate collation
ok( $t1, "Parsed test fragment file" );
my $c1 = $t1->collation;
"Relationship link prevented for a meta reading" );
}
+# Test 1.4: try to break a relationship near a meta reading
+$c1->add_relationship( 'r7.6', 'r7.3', { type => 'orthographic' } );
+try {
+ $c1->del_relationship( 'r7.6', 'r7.7' );
+ $c1->del_relationship( 'r7.6', 'r7.3' );
+ ok( 1, "Relationship broken with a meta reading as neighbor" );
+} catch {
+ ok( 0, "Relationship deletion failed with a meta reading as neighbor" );
+}
+
# Test 2.1: try to equate nodes that are prevented with a real intermediate
# equivalence
-my $t2 = Text::Tradition->new( 'input' => 'Self', 'file' => 't/data/legendfrag.xml' );
+my $t2;
+warning_is {
+ $t2 = Text::Tradition->new( 'input' => 'Self', 'file' => 't/data/legendfrag.xml' );
+} 'DROPPING r14.2 -> r8.1: Cannot set relationship on a meta reading',
+ "Got expected relationship drop warning on parse";
my $c2 = $t2->collation;
$c2->add_relationship( 'r9.2', 'r9.3', { 'type' => 'lexical' } );
my $trel2 = $c2->get_relationship( 'r9.2', 'r9.3' );
my $c = $self->collation;
## Assume validity is okay if we are initializing from scratch.
return ( 1, "initializing" ) unless $c->tradition->_initialized;
-
- if ( $rel eq 'transposition' || $rel eq 'repetition' ) {
+ if ( $rel eq 'transposition' || $rel eq 'repetition' ) {
# Check that the two readings do (for a repetition) or do not (for
# a transposition) appear in the same witness.
+ # TODO this might be called before witness paths are set...
my %seen_wits;
map { $seen_wits{$_} = 1 } $c->reading_witnesses( $source );
foreach my $w ( $c->reading_witnesses( $target ) ) {
$rel = $self->get_relationship( @$edge );
$self->_set_relationship( $rel, @vector );
}
- $self->_make_equivalence( $deleted, $kept, 1 );
+ $self->_make_equivalence( $deleted, $kept );
}
### Equivalence logic
# Equate two readings in the equivalence graph
sub _make_equivalence {
- my( $self, $source, $target, $removing ) = @_;
+ my( $self, $source, $target ) = @_;
# Get the source equivalent readings
my $seq = $self->equivalence( $source );
my $teq = $self->equivalence( $target );
# Nothing to do if they are already equivalent...
return if $seq eq $teq;
- # Get the readings equivalent to source
- my @sourcepool = @{$self->eqreadings( $seq )};
- # If we are removing the source reading entirely, don't push
- # it into the target pool.
- @sourcepool = grep { $_ ne $seq } @sourcepool if $removing;
+ my $sourcepool = $self->eqreadings( $seq );
# and add them to the target readings.
- push( @{$self->eqreadings( $teq )}, @sourcepool );
- map { $self->set_equivalence( $_, $teq ) } @sourcepool;
+ push( @{$self->eqreadings( $teq )}, @$sourcepool );
+ map { $self->set_equivalence( $_, $teq ) } @$sourcepool;
# Then merge the nodes in the equivalence graph.
foreach my $pred ( $self->equivalence_graph->predecessors( $seq ) ) {
- $self->equivalence_graph->add_edge( $pred, $teq )
- unless $teq eq $pred;
+ $self->equivalence_graph->add_edge( $pred, $teq );
}
foreach my $succ ( $self->equivalence_graph->successors( $seq ) ) {
- $self->equivalence_graph->add_edge( $teq, $succ )
- unless $teq eq $succ;
+ $self->equivalence_graph->add_edge( $teq, $succ );
}
$self->equivalence_graph->delete_vertex( $seq );
# TODO enable this after collation parsing is done
my $c = $self->collation;
foreach my $rdg ( @$newmembers ) {
foreach my $rp ( $c->sequence->predecessors( $rdg ) ) {
+ next unless $self->equivalence( $rp );
$self->equivalence_graph->add_edge( $self->equivalence( $rp ), $newgroup );
}
foreach my $rs ( $c->sequence->successors( $rdg ) ) {
+ next unless $self->equivalence( $rs );
$self->equivalence_graph->add_edge( $newgroup, $self->equivalence( $rs ) );
}
}
my( %old_pred, %old_succ );
foreach my $rdg ( @$oldmembers ) {
foreach my $rp ( $c->sequence->predecessors( $rdg ) ) {
+ next unless $self->equivalence( $rp );
$old_pred{$self->equivalence( $rp )} = 1;
}
foreach my $rs ( $c->sequence->successors( $rdg ) ) {
+ next unless $self->equivalence( $rs );
$old_succ{$self->equivalence( $rs )} = 1;
}
}
}
}
+=head2 equivalence_ranks
+
+Rank all vertices in the equivalence graph, and return a hash reference with
+vertex => rank mapping.
+
+=cut
+
+sub equivalence_ranks {
+ my $self = shift;
+ my $eqstart = $self->equivalence( $self->collation->start );
+ my $eqranks = { $eqstart => 0 };
+ my $rankeqs = { 0 => [ $eqstart ] };
+ my @curr_origin = ( $eqstart );
+ # A little iterative function.
+ while( @curr_origin ) {
+ @curr_origin = $self->_assign_rank( $eqranks, $rankeqs, @curr_origin );
+ }
+ return( $eqranks, $rankeqs );
+}
+
+sub _assign_rank {
+ my( $self, $node_ranks, $rank_nodes, @current_nodes ) = @_;
+ my $graph = $self->equivalence_graph;
+ # Look at each of the children of @current_nodes. If all the child's
+ # parents have a rank, assign it the highest rank + 1 and add it to
+ # @next_nodes. Otherwise skip it; we will return when the highest-ranked
+ # parent gets a rank.
+ my @next_nodes;
+ foreach my $c ( @current_nodes ) {
+ warn "Current reading $c has no rank!"
+ unless exists $node_ranks->{$c};
+ foreach my $child ( $graph->successors( $c ) ) {
+ next if exists $node_ranks->{$child};
+ my $highest_rank = -1;
+ my $skip = 0;
+ foreach my $parent ( $graph->predecessors( $child ) ) {
+ if( exists $node_ranks->{$parent} ) {
+ $highest_rank = $node_ranks->{$parent}
+ if $highest_rank <= $node_ranks->{$parent};
+ } else {
+ $skip = 1;
+ last;
+ }
+ }
+ next if $skip;
+ my $c_rank = $highest_rank + 1;
+ # print STDERR "Assigning rank $c_rank to node $child \n";
+ $node_ranks->{$child} = $c_rank if $node_ranks;
+ push( @{$rank_nodes->{$c_rank}}, $child ) if $rank_nodes;
+ push( @next_nodes, $child );
+ }
+ }
+ return @next_nodes;
+}
+
### Output logic
sub _as_graphml {