NAME
Marpa::PP::Semantics::Null - How Marpa Evaluates Null Rules and Symbols
NULL VALUES
A null node is a node which derives the zero-length, or empty string. This means that a null node cannot be the ancestor of any token nodes. In Marpa, null nodes are always leaf nodes.
Null nodes are of two kinds. A nulling symbol node corresponds to a nulling symbol. A nulled rule node represents a nulled rule.
For every null node there is a null node symbol, which is used to the determine the value of the null node. For a nulled rule node, the null node symbol is the nulled rule's left hand side symbol. For a nulling symbol node, the null node symbol is the nulling symbol.
The value of a null node is the null value of the null node symbol. The null value of a symbol comes from that symbol's null_value
property, if one is defined. Otherwise, the null value of the symbol comes from the grammar's default null value, as defined by the grammar's default_null_value
named argument. If neither the symbol null_value
property or the grammar's default_null_value
named argument is defined, a symbol's null value is a Perl undef
.
NULL SUBTREES
A null subtree is a subtree all of whose nodes are null. Marpa prunes all null subtrees back to their topmost null node. This means that all null nodes that remain in Marpa's virtual parse tree will be leaf nodes.
The "lost" semantics of the non-root nodes of null subtrees are usually not missed. Null subtrees cannot contain token nodes, so no token nodes are lost when null subtrees are pruned. As bushy as a null subtree might be, all of its nodes are null nodes.
All null nodes correspond to zero-length strings, so we are literally dealing here with the "semantics of nothing". In theory the semantics of nothing can be arbitrarily complex. In practice it should be possible to keep them simple.
If any application ever actually needs it, Marpa could implement a complex, and even dynamic, "semantics of nothing".
NULL SEQUENCE NODES
Rule nodes for sequences were mentioned above. Sequence nodes can also be null nodes. This happens with sequence rules which have a min
rule property of 0. Such a sequence rule can contain any number of sequence items, including zero items. When a sequence contains zero items, it must derive the zero-length string, and its node is a null node.
Sequence null nodes obey the rules for null nodes. Their value is that of a symbol -- the left hand side symbol of the nulled sequence rule.
When the node for a nullable sequence rule is a null node, its semantics comes from the null value for its left hand side symbol. When the node for a nullable sequence rule is not a null node, then it is a rule node and its semantics come from the rule. It's up to the application to ensure that the null value of the LHS symbol, when seen in the same contexts as the values returned by the semantic Perl closure for the sequence rule, "makes sense".
If necessary, an application can make sure that the LHS symbol of the sequence rule is not used for a conflicting purpose elsewhere. This dedicated symbol can then be given whatever semantics are necessary.
The rules for nodes in null subtrees apply with equal force to nodes for sequence rules. In a nulled subtree, the only node whose semantics matters is the root node of that subtree. If a zero-length sequence is in a nulled subtree, and that zero-length sequence is not the root node of that subtree, then its semantics will be completely ignored.
NULL SUBTREE EXAMPLE
In Marpa, a null node must be leaf node. Because Marpa prunes every null subtree back to its topmost null node, none of the non-root nodes in a null subtree are represented in Marpa's virtual parse tree. Here's an example:
sub L {
shift;
return 'L(' . ( join q{;}, map { $_ // '[ERROR!]' } @_ ) . ')';
}
sub R {
shift;
return 'R(' . ( join q{;}, map { $_ // '[ERROR!]' } @_ ) . ')';
}
sub S {
shift;
return 'S(' . ( join q{;}, map { $_ // '[ERROR!]' } @_ ) . ')';
}
my $grammar = Marpa::Grammar->new(
{ start => 'S',
actions => 'main',
rules => [
[ 'S', [qw/L R/] ],
[ 'L', [qw/A B X/] ],
[ 'L', [] ],
[ 'R', [qw/A B Y/] ],
[ 'R', [] ],
[ 'A', [] ],
[ 'B', [] ],
[ 'X', [] ],
[ 'Y', [] ],
],
symbols => {
L => { null_value => 'null L' },
R => { null_value => 'null R' },
A => { null_value => 'null A' },
B => { null_value => 'null B' },
X => { null_value => 'null X', terminal => 1 },
Y => { null_value => 'null Y', terminal => 1 },
},
}
);
$grammar->precompute();
my $recce = Marpa::Recognizer->new( { grammar => $grammar } );
$recce->read( 'X', 'x' );
If we write the unpruned parse tree one node per line in pre-order, depth-first, indenting children below their parents, we get something like this:
0: Rule Node, Rule: S := L R
1: Rule Node, Rule L := A B X
1.1: Null Node, Symbol A
1.2: Null Node, Symbol B
1.3: Token Node, Token value is 'x'
2: Rule Node, Rule R := A B Y
2.1: Null Node, Symbol A
2.2: Null Node, Symbol B
2.3: Null Node, Symbol Y
In this example, six nodes are nulled. Four of them are in a single subtree: 2, 2.1, 2.2 and 2.3. Marpa prunes every null subtree back to its null root node, which in this case is the node numbered 2.
The pruned tree looks like this
0: Rule Node, Rule: S := L R
1: Rule Node, Rule L := A B X
1.1: Null Node, Symbol A
1.2: Null Node, Symbol B
1.3: Token Node, Token value is 'x'
2: Null Node, Symbol R
Here is the output:
S(L(null A;null B;x);null R)
In the output we see
The null value for node 1.1: "
null A
".The null value for node 1.2: "
null B
".The token value for node 1.3: "
x
".An application of the semantic Perl closure for node 1.
The null value for node 2: "
null R
".An application of the semantic Perl closure for rule node 0.
We do not see any output for nodes 2.1, 2.2, or 2.3 because they were non-root nodes in the pruned subtree. We do see the null value for node 2, because after pruning it is a leaf node. We do not see an application of the semantic Perl closure for node 2, because after pruning, node 2 is not a rule node.
HOW TO IMPLEMENT A COMPLEX NULL SEMANTICS
In rare cases, your application may call for null values with a complex semantics. If an application's semantics of nothing, while complex, remains constant, you can handle it setting every nullable symbol's null_value
property to the value which your semantics produces when that nullable symbol is the root symbol of a null subtree.
If the values of an application's null values are not constants, Marpa can still calculate them. Here is a very general method: First, determine which of the application's nullable symbols have a dynamic semantics. Call these the dynamic nullables. Let the null_value
property of every dynamic nullable be a hash key. For every rule with a dynamic nullable on its right hand side, write the rule's semantic Perl closure so that it looks up that hash key in a hash whose values are Perl closures. The Perl closure can then use an arbitrarily complex semantics for calculating the value of the dynamic nullable.
COPYRIGHT AND LICENSE
Copyright 2011 Jeffrey Kegler
This file is part of Marpa::PP. Marpa::PP is free software: you can
redistribute it and/or modify it under the terms of the GNU Lesser
General Public License as published by the Free Software Foundation,
either version 3 of the License, or (at your option) any later version.
Marpa::PP is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser
General Public License along with Marpa::PP. If not, see
http://www.gnu.org/licenses/.