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|
//! This module implements the generation and insertion of item
//! derivation forests.
//!
//! This is used for the chain-rule machine to conveniently produce
//! item derivations into a forest. This forest can serve as a rough
//! approximation of the parse forests, and can be executed in other
//! semirings later on.
use super::*;
use crate::{atom::DefaultAtom, default::Error, item::default::DefaultForest, Edge};
use grammar::{Error as GrammarError, GrammarLabel, GrammarLabelType, TNT};
use graph::Graph;
use core::borrow::Borrow;
use std::collections::HashSet as Set;
/// A helper function to generate a fragment of forest.
///
/// It simply constructs a root node and then appends
/// successive nodes as successive children of the previous
/// node. Also the starting positions will all be set to the
/// same position.
///
/// If the input is empty, this returns an empty forest;
/// otherwise the result is not empty.
pub fn generate_fragment(
labels: impl AsRef<[GrammarLabelType]>,
pos: usize,
) -> Result<DefaultForest<ForestLabel<GrammarLabel>>, crate::default::Error> {
let mut labels_iter = labels.as_ref().iter();
let mut result: DefaultForest<ForestLabel<GrammarLabel>>;
if let Some(first_label) = labels_iter.next() {
result = DefaultForest::new_leaf(GrammarLabel::new(*first_label, pos));
let mut index = 0;
for label in labels_iter {
result.plant(
index,
DefaultForest::new_leaf(GrammarLabel::new(*label, pos)),
false,
)?;
// To prevent duplication of labels causing
// panics, we query the index of the new node.
index = result
.query_label(GrammarLabel::new(*label, pos).into())
// REVIEW: Perhaps a LabelNoNode error?
.ok_or(Error::Invalid)?;
}
} else {
result = Default::default();
}
Ok(result)
}
impl DefaultForest<ForestLabel<GrammarLabel>> {
/// Insert an item derivation forest into a recording forest.
///
/// We need the help of other things just for finding the correct
/// places to insert these item fragments.
pub fn insert_item(
&mut self,
label: Edge,
fragment: impl Borrow<DefaultForest<ForestLabel<GrammarLabel>>>,
atom_child_iter: impl Iterator<Item = usize>,
atom: &DefaultAtom,
) -> Result<PaSe, Error> {
/// Convert an error telling us that an index is out of bounds.
///
/// # Panics
///
/// The function panics if the error is not of the expected
/// kind.
fn index_out_of_bounds_conversion(ge: GrammarError) -> Error {
match ge {
GrammarError::IndexOutOfBounds(index, bound) => {
Error::IndexOutOfBounds(index, bound)
}
_ => Error::Invalid,
}
}
let fragment = fragment.borrow();
let pase = label.forest_source();
let parents: Vec<Parent> = {
let mut result = Vec::new();
if let Some(parent) = pase.parent() {
result.push(parent);
} else {
let (root, leaf) = pase.segment().unwrap();
let mut seen_nodes = Set::new();
let mut stack = vec![root];
while let Some(top) = stack.pop() {
if seen_nodes.contains(&top) {
continue;
}
seen_nodes.insert(top);
for (index, child) in self.children_of(top)?.enumerate() {
if child == leaf {
result.push(Parent::new(top, index));
} else {
stack.push(child);
}
}
}
}
result
};
for atom_child in atom_child_iter {
// Find reduction information.
let reduction_info = atom
.query_reduction(label.label(), atom_child)
.map_err(index_out_of_bounds_conversion)?;
let mut stack = parents.clone();
let mut second_stack = Vec::new();
// locate the nodes
for reduction_nt in reduction_info.iter().copied().flatten().rev() {
while let Some(node) = stack.pop() {
// REVIEW: A lot of labels appear here.
// Perhaps I need to refactor something?
if matches!(
self
.vertex_label(node.node())?
.ok_or_else(|| Error::NodeNoLabel(node.node()))?
.label()
.label(),
GrammarLabelType::TNT(TNT::Non(nt)) if nt == *reduction_nt
) {
for parent in self.parents_of(node.node())? {
debug_assert!(matches!(
self.vertex_label(parent.node()),
Ok(Some(label)) if
label
.label()
.label()
.rule()
.is_some()));
second_stack.extend(self.parents_of(parent.node())?.filter(|n| {
matches!(self.vertex_label(n.node()),
Ok(Some(label))
if matches!(
label.label().label().tnt(),
Some(TNT::Non(_))))
}));
}
}
}
std::mem::swap(&mut stack, &mut second_stack);
if stack.is_empty() {
break;
}
}
if stack.is_empty() {
return Err(Error::CannotPlant);
}
for parent in stack.into_iter() {
if parent.edge() + 1 >= self.degree(parent.node())? {
self.plant(parent.node(), fragment, false)?;
} else {
let nth_child = self.nth_child(parent.node(), parent.edge() + 1)?;
if self.is_prefix(nth_child, fragment)? {
// do nothing
continue;
}
let cloned_node = self.clone_node(nth_child)?;
self.plant(cloned_node, fragment, false)?;
}
}
}
let result = if fragment.nodes_len() == 2 {
let root_label = fragment.vertex_label(0)?.unwrap();
let leaf_label = fragment.vertex_label(1)?.unwrap();
// it has been planted, so should be safe.
let node = self.query_label(root_label).unwrap();
let edge = {
let mut result = None;
for (index, child) in self.children_of(node)?.enumerate() {
if matches!(self.vertex_label(child)?, Some(child_label) if child_label == leaf_label)
{
result = Some(index);
break;
}
}
if let Some(result) = result {
result
} else {
unreachable!("the forest is wrongly planted");
}
};
PaSe::Parent(node, edge)
} else {
let root_label = fragment.vertex_label(0)?.unwrap();
let leaf_label = fragment.vertex_label(fragment.nodes_len() - 1)?.unwrap();
PaSe::Segment(
self.query_label(root_label).unwrap(),
self.query_label(leaf_label).unwrap(),
)
};
Ok(result)
}
}
|
