X-Git-Url: http://git.shadowcat.co.uk/gitweb/gitweb.cgi?a=blobdiff_plain;f=lib%2FText%2FTradition%2FAnalysis.pm;h=fda51376077c9e67781e1c5e134c203704fd706a;hb=679f17e1a60a81370df8cbb49b94a2b5d19e3a98;hp=049211b72b2d412cb00fd2c55ee293ced07c4df4;hpb=bebec0e9db285a2161d08667ba98fa3bcb91d9e4;p=scpubgit%2Fstemmatology.git

diff --git a/lib/Text/Tradition/Analysis.pm b/lib/Text/Tradition/Analysis.pm
index 049211b..fda5137 100644
--- a/lib/Text/Tradition/Analysis.pm
+++ b/lib/Text/Tradition/Analysis.pm
@@ -3,7 +3,11 @@ package Text::Tradition::Analysis;
 use strict;
 use warnings;
 use Benchmark;
+use Encode qw/ encode_utf8 /;
 use Exporter 'import';
+use Graph;
+use JSON qw/ encode_json decode_json /;
+use LWP::UserAgent;
 use Text::Tradition;
 use Text::Tradition::Stemma;
 
@@ -37,15 +41,24 @@ between readings are actually kept.
 
 =head1 SUBROUTINES
 
-=head2 run_analysis( $tradition, $stemma_id, @merge_relationship_types )
+=head2 run_analysis( $tradition, %opts )
 
-Runs the analysis described in analyze_variant_location on every location
-in the collation of the given tradition, against the stemma specified in
-$stemma_id.  If $stemma_id is not specified, it defaults to 0 (referencing
-the first stemma saved for the tradition.)
+Runs the analysis described in analyze_variant_location on every location in the 
+collation of the given tradition, with the given options. These include:
 
-The optional @merge_relationship_types contains a list of relationship types 
-to treat as equivalent for the analysis.
+=over 4
+
+=item * stemma_id - Specify which of the tradition's stemmata to use. Default
+is 0 (i.e. the first).
+
+=item * ranks - Specify a list of location ranks to analyze; exclude the rest.
+
+=item * merge_types - Specify a list of relationship types, where related readings 
+should be treated as identical for the purposes of analysis.
+
+=item * exclude_type1 - Exclude those ranks whose groupings have only type-1 variants.
+
+=back
 
 =begin testing
 
@@ -59,48 +72,120 @@ my $tradition = Text::Tradition->new( 'input' => 'TEI',
 my $s = $tradition->add_stemma( 'dotfile' => 't/data/florilegium.dot' );
 is( ref( $s ), 'Text::Tradition::Stemma', "Added stemma to tradition" );
 
+my %expected_genealogical = (
+	1 => 0,
+	2 => 1,
+	3 =>  0,
+	5 =>  0,
+	7 =>  0,
+	8 =>  0,
+	10 => 0,
+	13 => 1,
+	33 => 0,
+	34 => 0,
+	37 => 0,
+	60 => 0,
+	81 => 1,
+	84 => 0,
+	87 => 0,
+	101 => 0,
+	102 => 0,
+	122 => 1,
+	157 => 0,
+	166 => 1,
+	169 => 1,
+	200 => 0,
+	216 => 1,
+	217 => 1,
+	219 => 1,
+	241 => 1,
+	242 => 1,
+	243 => 1,
+);
+
 my $data = run_analysis( $tradition );
-# TODO Check genealogical count
-is( $data->{'genealogical_count'}, 13, "Got right genealogical count" );
-is( $data->{'conflict_count'}, 16, "Got right conflict count" );
-is( $data->{'variant_count'}, 28, "Got right total variant number" );
+foreach my $row ( @{$data->{'variants'}} ) {
+	# Account for rows that used to be "not useful"
+	unless( exists $expected_genealogical{$row->{'id'}} ) {
+		$expected_genealogical{$row->{'id'}} = 1;
+	}
+	is( $row->{'genealogical'}, $expected_genealogical{$row->{'id'}}, 
+		"Got correct genealogical flag for row " . $row->{'id'} );
+}
+is( $data->{'variant_count'}, 58, "Got right total variant number" );
+# TODO Make something meaningful of conflict count, maybe test other bits
 
 =end testing
 
 =cut
 
 sub run_analysis {
-	my( $tradition, $stemma_id, @collapse ) = @_;
-	$stemma_id = 0 unless $stemma_id;
-	
-	# Run the variant analysis on every rank in the graph that doesn't
-	# have a common reading. Return the results.
-	my @variants; # holds results from analyze_variant_location
-	my $genealogical; # counter of 'genealogical' variants
-	my $conflicts;    # counter of conflicting readings
-	
-	# Find and mark 'common' ranks for exclusion.
-	my %common_rank;
-	foreach my $rdg ( $tradition->collation->common_readings ) {
-		$common_rank{$rdg->rank} = 1;
+	my( $tradition, %opts ) = @_;
+	my $c = $tradition->collation;
+
+	my $stemma_id = $opts{'stemma_id'} || 0;
+	my @ranks = ref( $opts{'ranks'} ) eq 'ARRAY' ? @{$opts{'ranks'}} : ();
+	my @collapse = ref( $opts{'merge_types'} ) eq 'ARRAY' ? @{$opts{'merge_types'}} : ();
+
+	# Get the stemma	
+	my $stemma = $tradition->stemma( $stemma_id );
+
+	# Figure out which witnesses we are working with
+	my @lacunose = $stemma->hypotheticals;
+	my @tradition_wits = map { $_->sigil } $tradition->witnesses;
+	map { push( @tradition_wits, $_->sigil.$c->ac_label ) if $_->is_layered } 
+		$tradition->witnesses;
+	push( @lacunose, _symmdiff( [ $stemma->witnesses ], \@tradition_wits ) );
+
+	# Find and mark 'common' ranks for exclusion, unless they were
+	# explicitly specified.
+	unless( @ranks ) {
+		my %common_rank;
+		foreach my $rdg ( $c->common_readings ) {
+			$common_rank{$rdg->rank} = 1;
+		}
+		@ranks = grep { !$common_rank{$_} } ( 1 .. $c->end->rank-1 );
 	}
 	
-	foreach my $rank ( 1 .. $tradition->collation->end->rank-1 ) {
-		next if $common_rank{$rank};
-		my $variant_row = analyze_variant_location( 
-			$tradition, $rank, $stemma_id, @collapse );
-		next unless $variant_row;
-		push( @variants, $variant_row );
-		$genealogical++ if $variant_row->{'genealogical'};
-		$conflicts += grep { $_->{'conflict'} } @{$variant_row->{'readings'}};
+	# Group the variants to send to the solver
+	my @groups;
+	my %lacunae;
+	foreach my $rank ( @ranks ) {
+		my $missing = [ @lacunose ];
+		my $rankgroup = group_variants( $tradition, $rank, $missing, \@collapse );
+		if( $opts{'exclude_type1'} ) {
+			# Check to see whether this is a "useful" group.
+			my( $rdgs, $grps ) = _useful_variant( $rankgroup );
+			next unless @$rdgs;
+		}
+		push( @groups, $rankgroup );
+		$lacunae{$rank} = $missing;
 	}
+	$DB::single = 1;
+	# Parse the answer
+	my $answer = solve_variants( $stemma, @groups );
+
+	# Do further analysis on the answer
+	my $conflict_count = 0;
+	foreach my $idx ( 0 .. $#ranks ) {
+		my $location = $answer->{'variants'}->[$idx];
+		# Add the rank back in
+		$location->{'id'} = $ranks[$idx];
+		# Add the lacunae back in
+		$location->{'missing'} = $lacunae{$ranks[$idx]};
+		# Run the extra analysis we need.
+		analyze_location( $tradition, $stemma->graph, $location );
+		# Add the reading text back in
+		foreach my $rdghash ( @{$location->{'readings'}} ) {
+			$conflict_count++ 
+				if exists $rdghash->{'conflict'} && $rdghash->{'conflict'};
+			my $rdg = $c->reading( $rdghash->{'readingid'} );
+			$rdghash->{'text'} = $rdg ? $rdg->text : $rdghash->{'readingid'};
+		}
+	}
+	$answer->{'conflict_count'} = $conflict_count;
 	
-	return {
-		'variants' => \@variants,
-		'variant_count' => scalar @variants, # TODO redundant
-		'conflict_count' => $conflicts,
-		'genealogical_count' => $genealogical,
-		};
+	return $answer;
 }
 
 =head2 group_variants( $tradition, $rank, $lacunose, @merge_relationship_types )
@@ -110,8 +195,8 @@ relationships in @merge_relationship_types as equivalent.  $lacunose should
 be a reference to an array, to which the sigla of lacunose witnesses at this 
 rank will be appended.
 
-Returns two ordered lists $readings, $groups, where $readings->[$n] is attested
-by the witnesses listed in $groups->[$n].
+Returns a hash $group_readings where $rdg is attested by the witnesses listed 
+in $group_readings->{$rdg}.
 
 =cut
 
@@ -119,36 +204,38 @@ by the witnesses listed in $groups->[$n].
 sub group_variants {
 	my( $tradition, $rank, $lacunose, $collapse ) = @_;
 	my $c = $tradition->collation;
+	my $aclabel =  $c->ac_label;
 	# Get the alignment table readings
 	my %readings_at_rank;
 	my @gap_wits;
-	foreach my $tablewit ( @{$tradition->collation->alignment_table->{'alignment'}} ) {
+	foreach my $tablewit ( @{$c->alignment_table->{'alignment'}} ) {
 		my $rdg = $tablewit->{'tokens'}->[$rank-1];
+		my $wit = $tablewit->{'witness'};
 		if( $rdg && $rdg->{'t'}->is_lacuna ) {
-			_add_to_witlist( $tablewit->{'witness'}, $lacunose, 
-				$tradition->collation->ac_label );
+			_add_to_witlist( $wit, $lacunose, $aclabel );
 		} elsif( $rdg ) {
 			$readings_at_rank{$rdg->{'t'}->text} = $rdg->{'t'};
 		} else {
-			_add_to_witlist( $tablewit->{'witness'}, \@gap_wits, 
-				$tradition->collation->ac_label );
+			_add_to_witlist( $wit, \@gap_wits, $aclabel );
 		}
 	}
 	
 	# Group the readings, collapsing groups by relationship if needed
 	my %grouped_readings;
-	foreach my $rdg ( sort { $b->witnesses <=> $a->witnesses } values %readings_at_rank ) {
+	foreach my $rdg ( sort { $b->witnesses <=> $a->witnesses } 
+						   values %readings_at_rank ) {
 		# Skip readings that have been collapsed into others.
-		next if exists $grouped_readings{$rdg->text} && !$grouped_readings{$rdg->text};
+		next if exists $grouped_readings{$rdg->id} && !$grouped_readings{$rdg->id};
 		my @wits = $rdg->witnesses;
 		if( $collapse ) {
 			my $filter = sub { my $r = $_[0]; grep { $_ eq $r->type } @$collapse; };
 			foreach my $other ( $rdg->related_readings( $filter ) ) {
-				push( @wits, $other->witnesses );
-				$grouped_readings{$other->text} = 0;
+				my @otherwits = $other->witnesses;
+				push( @wits, @otherwits );
+				$grouped_readings{$other->id} = 0;
 			}
 		}
-		$grouped_readings{$rdg->text} = \@wits;	
+		$grouped_readings{$rdg->id} = \@wits;	
 	}
 	$grouped_readings{'(omitted)'} = \@gap_wits if @gap_wits;
 	# Get rid of our collapsed readings
@@ -159,68 +246,316 @@ sub group_variants {
 	return \%grouped_readings;
 }
 
-=head2 analyze_variant_location( $tradition, $rank, $stemma_id, @merge_relationship_types )
+=head2 solve_variants( $graph, @groups ) 
+
+Sends the set of groups to the external graph solver service and returns
+a cleaned-up answer, adding the rank IDs back where they belong.
+
+The JSON has the form 
+  { "graph": [ stemmagraph DOT string without newlines ],
+    "groupings": [ array of arrays of groups, one per rank ] }
+    
+The answer has the form 
+  { "variants" => [ array of variant location structures ],
+    "variant_count" => total,
+    "conflict_count" => number of conflicts detected,
+    "genealogical_count" => number of solutions found }
+    
+=cut
+
+sub solve_variants {
+	my( $stemma, @groups ) = @_;
+
+	# Make the json with stemma + groups
+	my $groupings = [];
+	foreach my $ghash ( @groups ) {
+		my @grouping;
+		foreach my $k ( keys %$ghash ) {
+			push( @grouping, $ghash->{$k} );
+		}
+		push( @$groupings, \@grouping );
+	}
+	## Witness map is a HACK to get around limitations in node names from IDP
+	my $witness_map = {};
+	my $json = encode_json( _safe_wit_strings( $stemma, $groupings, $witness_map ) );
+
+	# Send it off and get the result
+	my $solver_url = 'http://byzantini.st/cgi-bin/graphcalc.cgi';
+	my $ua = LWP::UserAgent->new();
+	my $resp = $ua->post( $solver_url, 'Content-Type' => 'application/json', 
+						  'Content' => $json );
+						  
+	my $answer;
+	my $used_idp;
+	if( $resp->is_success ) {
+		$answer = _desanitize_names( decode_json( $resp->content ), $witness_map );
+		$used_idp = 1;
+	} else {
+		# Fall back to the old method.
+		warn "IDP solver returned " . $resp->status_line . " / " . $resp->content
+			. "; falling back to perl method";
+		$answer = perl_solver( $stemma, @$groupings );
+	}
+	
+	# Fold the result back into what we know about the groups.
+	my $variants = [];
+	my $genealogical = 0;
+	foreach my $idx ( 0 .. $#groups ) {
+		my( $calc_groups, $result ) = @{$answer->[$idx]};
+		if( $result ) {
+			$genealogical++;
+			# Prune the calculated groups, in case the IDP solver failed to.
+			if( $used_idp ) {
+				my @pruned_groups;
+				foreach my $cg ( @$calc_groups ) {
+					my @pg = _prune_group( $cg, $stemma );
+					push( @pruned_groups, \@pg );
+				}
+				$calc_groups = \@pruned_groups;
+			}
+		}
+		my $input_group = $groups[$idx];
+		foreach my $k ( sort keys %$input_group ) {
+			my $cg = shift @$calc_groups;
+			$input_group->{$k} = $cg;
+		}
+		my $vstruct = { 
+			'genealogical' => $result,
+			'readings' => [],
+		};
+		foreach my $k ( keys %$input_group ) {
+			push( @{$vstruct->{'readings'}}, 
+				  { 'readingid' => $k, 'group' => $input_group->{$k}} );
+		}
+		push( @$variants, $vstruct );
+	}
+	
+	return { 'variants' => $variants, 
+			 'variant_count' => scalar @$variants,
+			 'genealogical_count' => $genealogical };
+}
+
+#### HACKERY to cope with IDP's limited idea of what a node name looks like ###
+
+sub _safe_wit_strings {
+	my( $stemma, $groupings, $witness_map ) = @_;
+	my $safegraph = Graph->new();
+	# Convert the graph to a safe representation and store the conversion.
+	foreach my $n ( $stemma->graph->vertices ) {
+		my $sn = _safe_witstr( $n );
+		warn "Ambiguous stringification $sn for $n and " . $witness_map->{$sn}
+			if exists $witness_map->{$sn};
+		$witness_map->{$sn} = $n;
+		$safegraph->add_vertex( $sn );
+		$safegraph->set_vertex_attributes( $sn, 
+			$stemma->graph->get_vertex_attributes( $n ) );
+	}
+	foreach my $e ( $stemma->graph->edges ) {
+		my @safe_e = ( _safe_witstr( $e->[0] ), _safe_witstr( $e->[1] ) );
+		$safegraph->add_edge( @safe_e );
+	}
+	my $safe_stemma = Text::Tradition::Stemma->new( 
+		'collation' => $stemma->collation, 'graph' => $safegraph );
+		
+	# Now convert the witness groupings to a safe representation.
+	my $safe_groupings = [];
+	foreach my $grouping ( @$groupings ) {
+		my $safe_grouping = [];
+		foreach my $group ( @$grouping ) {
+			my $safe_group = [];
+			foreach my $n ( @$group ) {
+				my $sn = _safe_witstr( $n );
+				warn "Ambiguous stringification $sn for $n and " . $witness_map->{$sn}
+					if exists $witness_map->{$sn} && $witness_map->{$sn} ne $n;
+				$witness_map->{$sn} = $n;
+				push( @$safe_group, $sn );
+			}
+			push( @$safe_grouping, $safe_group );
+		}
+		push( @$safe_groupings, $safe_grouping );
+	}
+	
+	# Return it all in the struct we expect.  We have stored the reductions
+	# in the $witness_map that we were passed.
+	return { 'graph' => $safe_stemma->editable( ' ' ), 'groupings' => $safe_groupings };
+}
+
+sub _safe_witstr {
+	my $witstr = shift;
+	$witstr =~ s/\s+/_/g;
+	$witstr =~ s/[^\w\d-]//g;
+	return $witstr;
+}
+
+sub _desanitize_names {
+	my( $jsonstruct, $witness_map ) = @_;
+	my $result = [];
+	foreach my $grouping ( @$jsonstruct ) {
+		my $real_grouping = [];
+		foreach my $element ( @$grouping ) {
+			if( ref( $element ) eq 'ARRAY' ) {
+				# it's the groupset.
+				my $real_groupset = [];
+				foreach my $group ( @$element ) {
+					my $real_group = [];
+					foreach my $n ( @$group ) {
+						my $rn = $witness_map->{$n};
+						push( @$real_group, $rn );
+					}
+					push( @$real_groupset, $real_group );
+				}
+				push( @$real_grouping, $real_groupset );
+			} else {
+				# It is the boolean, not actually a group.
+				push( @$real_grouping, $element );
+			}
+		}
+		push( @$result, $real_grouping );
+	}
+	return $result;
+}
+
+### END HACKERY ###
+
+=head2 analyze_location ( $tradition, $graph, $location_hash )
+
+Given the tradition, its stemma graph, and the solution from the graph solver,
+work out the rest of the information we want.  For each reading we need missing, 
+conflict, reading_parents, independent_occurrence, followed, not_followed, and follow_unknown.  Alters the location_hash in place.
+
+=cut
+
+sub analyze_location {
+	my ( $tradition, $graph, $variant_row ) = @_;
+	
+	# Make a hash of all known node memberships, and make the subgraphs.
+	my $contig = {};
+	my $reading_roots = {};
+	my $subgraph = {};
+    foreach my $rdghash ( @{$variant_row->{'readings'}} ) {
+    	my $rid = $rdghash->{'readingid'};
+		map { $contig->{$_} = $rid } @{$rdghash->{'group'}};
+        
+        # Make the subgraph.
+        my $part = $graph->copy;
+		my %these_vertices;
+		map { $these_vertices{$_} = 1 } @{$rdghash->{'group'}};
+		$part->delete_vertices( grep { !$these_vertices{$_} } $part->vertices );
+		$subgraph->{$rid} = $part;
+		# Get the reading roots.
+		map { $reading_roots->{$_} = $rid } $part->predecessorless_vertices;
+	}
+	
+	# Now that we have all the node group memberships, calculate followed/
+    # non-followed/unknown values for each reading.  Also figure out the
+    # reading's evident parent(s).
+    foreach my $rdghash ( @{$variant_row->{'readings'}} ) {
+    	# Group string key - TODO do we need this?
+        my $gst = wit_stringify( $rdghash->{'group'} );
+        my $rid = $rdghash->{'readingid'};
+        # Get the subgraph
+        my $part = $subgraph->{$rid};
+        
+        # Start figuring things out.  
+        my @roots = $part->predecessorless_vertices;
+        $rdghash->{'independent_occurrence'} = scalar @roots;
+        $rdghash->{'followed'} = scalar( $part->vertices ) - scalar( @roots );
+        # Find the parent readings, if any, of this reading.
+        my %rdgparents;
+        foreach my $wit ( @roots ) {
+        	# Look in the main stemma to find this witness's extant or known-reading
+        	# immediate ancestor(s), and look up the reading that each ancestor olds.
+			my @check = $graph->predecessors( $wit );
+			while( @check ) {
+				my @next;
+				foreach my $wparent( @check ) {
+					my $preading = $contig->{$wparent};
+					if( $preading ) {
+						$rdgparents{$preading} = 1;
+					} else {
+						push( @next, $graph->predecessors( $wparent ) );
+					}
+				}
+				@check = @next;
+			}
+		}
+		$rdghash->{'reading_parents'} = [ keys %rdgparents ];
+		
+		# Find the number of times this reading was altered, and the number of
+		# times we're not sure.
+		my( %nofollow, %unknownfollow );
+		foreach my $wit ( $part->vertices ) {
+			foreach my $wchild ( $graph->successors( $wit ) ) {
+				next if $part->has_vertex( $wchild );
+				if( $reading_roots->{$wchild} && $contig->{$wchild} ) {
+					# It definitely changed here.
+					$nofollow{$wchild} = 1;
+				} elsif( !($contig->{$wchild}) ) {
+					# The child is a hypothetical node not definitely in
+					# any group. Answer is unknown.
+					$unknownfollow{$wchild} = 1;
+				} # else it's a non-root node in a known group, and therefore
+				  # is presumed to have its reading from its group, not this link.
+			}
+		}
+		$rdghash->{'not_followed'} = keys %nofollow;
+		$rdghash->{'follow_unknown'} = keys %unknownfollow;
+		
+		# Now say whether this reading represents a conflict.
+		unless( $variant_row->{'genealogical'} ) {
+			$rdghash->{'conflict'} = @roots != 1;
+		}		
+    }
+}
+
+
+=head2 perl_solver( $tradition, $rank, $stemma_id, @merge_relationship_types )
+
+** NOTE ** This method should hopefully not be called - it is not guaranteed 
+to be correct.  Serves as a backup for the real solver.
 
 Runs an analysis of the given tradition, at the location given in $rank, 
 against the graph of the stemma specified in $stemma_id.  The argument 
 @merge_relationship_types is an optional list of relationship types for
 which readings so related should be treated as equivalent.
 
-Returns a data structure as follows:
+Returns a nested array data structure as follows:
 
- { 	'id' => $rank,
- 	'genealogical' => boolean,
- 	'readings => [ { text => $reading_text, 
- 					 group => [ witnesses ], 
- 					 conflict => [ conflicting ], 
- 					 missing => [ excluded ] }, ... ]
- }
-where 'conflicting' is the list of witnesses whose readings conflict with
-this group, and 'excluded' is the list of witnesses either not present in
-the stemma or lacunose at this location.
+ [ [ group_list, is_genealogical ], [ group_list, is_genealogical ] ... ]
+ 
+where the group list is the array of arrays passed in for each element of @groups,
+possibly with the addition of hypothetical readings.
+ 
 
 =cut
 
-sub analyze_variant_location {
-	my( $tradition, $rank, $sid, @collapse ) = @_;
-	# Get the readings in this tradition at this rank
-	my @rank_rdgs = grep { $_->rank == $rank } $tradition->collation->readings;
-	# Get the applicable stemma
-	my $undirected; # TODO Allow undirected distance tree analysis too
-	my $stemma = $tradition->stemma( $sid );
+sub perl_solver {
+	my( $stemma, @groups ) = @_;
 	my $graph = $stemma->graph;
-	# Figure out which witnesses we are working with
-	my @lacunose = $stemma->hypotheticals;
-	push( @lacunose, _symmdiff( [ $stemma->witnesses ], 
-		[ map { $_->sigil } $tradition->witnesses ] ) );
-
-	# Now group the readings
-	my( $readings, $groups ) = _useful_variant( 
-		group_variants( $tradition, $rank, \@lacunose, \@collapse ), 
-		$graph, $tradition->collation->ac_label );
-	return unless scalar @$readings;
-	my $group_readings = {};
-	# Lookup table group string -> readings
-	foreach my $x ( 0 .. $#$groups ) {
-		$group_readings->{wit_stringify( $groups->[$x] )} = $readings->[$x];
+	my @answer;
+	foreach my $g ( @groups ) {
+		push( @answer, _solve_variant_location( $graph, $g ) );
 	}
+	return \@answer;
+}
 
+sub _solve_variant_location {
+	my( $graph, $groups ) = @_;
 	# Now do the work.	
     my $contig = {};
     my $subgraph = {};
     my $is_conflicted;
     my $conflict = {};
-    my %reading_roots;
-    my $variant_row = { 'id' => $rank, 'readings' => [] };
+
     # Mark each ms as in its own group, first.
     foreach my $g ( @$groups ) {
         my $gst = wit_stringify( $g );
         map { $contig->{$_} = $gst } @$g;
     }
+
     # Now for each unmarked node in the graph, initialize an array
     # for possible group memberships.  We will use this later to
     # resolve potential conflicts.
-    $DB::single = 1 if $rank == 636;
     map { $contig->{$_} = [] unless $contig->{$_} } $graph->vertices;
     foreach my $g ( sort { scalar @$b <=> scalar @$a } @$groups ) {
         my $gst = wit_stringify( $g );  # This is the group name
@@ -231,42 +566,34 @@ sub analyze_variant_location {
             grep { !ref( $contig->{$_} ) && $contig->{$_} ne $gst } $graph->vertices );
                 
         # Now look to see if our group is connected.
-        if( $undirected ) { # For use with distance trees etc.
-            # Find all vertices reachable from the first (arbitrary) group
-            # member.  If we are genealogical this should include them all.
-            my $reachable = {}; 
-            map { $reachable->{$_} = 1 } $part->all_reachable( $g->[0] );
-            # TODO This is a terrible way to do distance trees, since all
-            # non-leaf nodes are included in every graph part now. We may
-            # have to go back to SPDP.
-        } else {
-            if( @$g > 1 ) {
-                # We have to take directionality into account.
-                # How many root nodes do we have?
-                my @roots = grep { ref( $contig->{$_} ) || $contig->{$_} eq $gst } 
-                    $part->predecessorless_vertices;
-                # Assuming that @$g > 1, find the first root node that has at
-                # least one successor belonging to our group. If this reading
-                # is genealogical, there should be only one, but we will check
-                # that implicitly later.
-                foreach my $root ( @roots ) {
-                    # Prune the tree to get rid of extraneous hypotheticals.
-                    $root = _prune_subtree( $part, $root, $contig );
-                    next unless $root;
-                    # Save this root for our group.
-                    push( @group_roots, $root );
-                    # Get all the successor nodes of our root.
-                }
-            } else {
-            	# Dispense with the trivial case of one reading.
-                @group_roots = @$g;
-                _prune_subtree( $part, @group_roots, $contig );
-            }
+		if( @$g > 1 ) {
+			# We have to take directionality into account.
+			# How many root nodes do we have?
+			my @roots = grep { ref( $contig->{$_} ) || $contig->{$_} eq $gst } 
+				$part->predecessorless_vertices;
+			# Assuming that @$g > 1, find the first root node that has at
+			# least one successor belonging to our group. If this reading
+			# is genealogical, there should be only one, but we will check
+			# that implicitly later.
+			foreach my $root ( @roots ) {
+				# Prune the tree to get rid of extraneous hypotheticals.
+				$root = _prune_subtree( $part, $root, $contig );
+				next unless $root;
+				# Save this root for our group.
+				push( @group_roots, $root );
+				# Get all the successor nodes of our root.
+			}
+		} else {
+			# Dispense with the trivial case of one reading.
+			my $wit = $g->[0];
+			@group_roots = ( $wit );
+			foreach my $v ( $part->vertices ) {
+				$part->delete_vertex( $v ) unless $v eq $wit;
+			}
         }
         
-        map { $reading_roots{$_} = 1 } @group_roots;
         if( @group_roots > 1 ) {
-        	$conflict->{$group_readings->{$gst}} = 1;
+        	$conflict->{$gst} = 1;
         	$is_conflicted = 1;
         }
         # Paint the 'hypotheticals' with our group.
@@ -279,13 +606,8 @@ sub analyze_variant_location {
 		}
         
         
-        # Start to write the reading, and save the group subgraph.
-        my $reading = { 'text' => $group_readings->{$gst},
-                        'missing' => wit_stringify( \@lacunose ),
-                        'group' => $gst };  # This will change if we find no conflict
 		# Save the relevant subgraph.
 		$subgraph->{$gst} = $part;
-        push( @{$variant_row->{'readings'}}, $reading );
     }
     
 	# For each of our hypothetical readings, flatten its 'contig' array if
@@ -335,7 +657,7 @@ sub analyze_variant_location {
                 		# $h is needed by this group.
                 		if( exists( $still_contig->{$h} ) ) {
                 			# Conflict!
-                			$conflict->{$group_readings->{$gst}} = 1;
+                			$conflict->{$gst} = 1;
                 			$still_contig->{$h} = '';
                 		} else {
                 			$still_contig->{$h} = $gst;
@@ -356,7 +678,7 @@ sub analyze_variant_location {
 							# We need $h.
 							if( exists $still_contig->{$h} ) {
 								# Conflict!
-								$conflict->{$group_readings->{$gst}} = 1;
+								$conflict->{$gst} = 1;
 								$still_contig->{$h} = '';
 							} else {
 								$still_contig->{$h} = $gst;
@@ -376,61 +698,35 @@ sub analyze_variant_location {
 		}
     } # end if @resolve
     
-    # Now that we have all the node group memberships, calculate followed/
-    # non-followed/unknown values for each reading.  Also figure out the
-    # reading's evident parent(s).
-    foreach my $rdghash ( @{$variant_row->{'readings'}} ) {
-        my $gst = $rdghash->{'group'};
-        my $part = $subgraph->{$gst};
-        my @roots = $part->predecessorless_vertices;
-        $rdghash->{'independent_occurrence'} = scalar @roots;
-        $rdghash->{'followed'} = scalar( $part->vertices ) - scalar( @roots );
-        # Find the parent readings, if any, of this reading.
-        my @rdgparents;
-        foreach my $wit ( @roots ) {
-        	# Look in the main stemma to find this witness's parent(s), and look
-        	# up the reading that the parent holds.
-        	foreach my $wparent( $graph->predecessors( $wit ) ) {
-        		my $pgroup = $contig->{$wparent};
-        		if( $pgroup ) {
-        			push( @rdgparents, $group_readings->{$pgroup} );
-        		}
-        	}
-		}
-		$rdghash->{'reading_parents'} = \@rdgparents;
-		
-		# Find the number of times this reading was altered, and the number of
-		# times we're not sure.
-		my( %nofollow, %unknownfollow );
-		foreach my $wit ( $part->vertices ) {
-			foreach my $wchild ( $graph->successors( $wit ) ) {
-				next if $part->has_vertex( $wchild );
-				if( $reading_roots{$wchild} && $contig->{$wchild} ) {
-					# It definitely changed here.
-					$nofollow{$wchild} = 1;
-				} elsif( !($contig->{$wchild}) ) {
-					# The child is a hypothetical node not definitely in
-					# any group. Answer is unknown.
-					$unknownfollow{$wchild} = 1;
-				} # else it's a non-root node in a known group, and therefore
-				  # is presumed to have its reading from its group, not this link.
-			}
-		}
-		$rdghash->{'not_followed'} = keys %nofollow;
-		$rdghash->{'follow_unknown'} = keys %unknownfollow;
+    my $is_genealogical = keys %$conflict ? JSON::false : JSON::true;
+	my $variant_row = [ [], $is_genealogical ];
+	# Fill in the groupings from $contig.
+	foreach my $g ( @$groups ) {
+    	my $gst = wit_stringify( $g );
+    	my @realgroup = grep { $contig->{$_} eq $gst } keys %$contig;
+    	push( @{$variant_row->[0]}, \@realgroup );
     }
-    
-    # Now write the group and conflict information into the respective rows.
-    foreach my $rdghash ( @{$variant_row->{'readings'}} ) {
-        $rdghash->{'conflict'} = $conflict->{$rdghash->{'text'}};
-        my @members = grep { $contig->{$_} eq $rdghash->{'group'} } keys %$contig;
-        $rdghash->{'group'} = wit_stringify( \@members );
-    }
-    
-    $variant_row->{'genealogical'} = !( keys %$conflict );
     return $variant_row;
 }
 
+sub _prune_group {
+	my( $group, $stemma ) = @_;
+	# Get these into a form prune_subtree will recognize. Make a "contighash"
+	my $hypohash = {};
+	map { $hypohash->{$_} = 1 } @$group;
+	# ...with reference values for hypotheticals.
+	map { $hypohash->{$_} = [] } $stemma->hypotheticals;
+	# Make our subgraph
+	my $subgraph = $stemma->graph->copy;
+	map { $subgraph->delete_vertex( $_ ) unless exists $hypohash->{$_} }
+		$subgraph->vertices;
+	# ...and find the root.
+	my( $root ) = $subgraph->predecessorless_vertices;
+	# Now prune and return the remaining vertices.
+	_prune_subtree( $subgraph, $root, $hypohash );
+	return $subgraph->vertices;
+}
+
 sub _prune_subtree {
     my( $tree, $root, $contighash ) = @_;
     # First, delete hypothetical leaves / orphans until there are none left.