3 files changed, 146 insertions, 209 deletions

diff --git a/forest/src/default.rs b/forest/src/default.rs
index 5e438d4..d3970e9 100644
--- a/forest/src/default.rs
+++ b/forest/src/default.rs
@@ -1,141 +1,21 @@
 //! This file provides a default implementation for the
 //! [`Forest`][crate::Forest] trait.
 
+#[allow(unused_imports)]
 use super::*;
+#[allow(unused_imports)]
 use graph::{error::Error as GraphError, ALGraph, Graph};
 
+#[allow(unused_imports)]
 use std::collections::{hash_set::Iter, HashMap, HashSet};
 
-#[derive(Debug, Clone)]
-pub struct DefaultForest<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> {
-    graph: ALGraph,
-    vertex_labels: HashMap<usize, NodeLabel>,
-    edge_labels: HashMap<(usize, usize), EdgeLabel>,
-    plugins: HashSet<usize>,
-    plugouts: HashSet<usize>,
-}
+// TODO: Use PLGraph instead.
 
-impl<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> Default for DefaultForest<NodeLabel, EdgeLabel> {
-    fn default() -> Self {
-        Self {
-            graph: Default::default(),
-            vertex_labels: Default::default(),
-            edge_labels: Default::default(),
-            plugins: Default::default(),
-            plugouts: Default::default(),
-        }
-    }
-}
-
-impl<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> Graph for DefaultForest<NodeLabel, EdgeLabel> {
-    type Iter<'a> = <ALGraph as Graph>::Iter<'a>
-    where
-        Self: 'a;
-
-    fn is_empty(&self) -> bool {
-        self.graph.is_empty()
-    }
-
-    fn nodes_len(&self) -> usize {
-        self.graph.nodes_len()
-    }
-
-    fn children_of(&self, node_id: usize) -> Result<Self::Iter<'_>, GraphError> {
-        self.graph.children_of(node_id)
-    }
-
-    fn degree(&self, node_id: usize) -> Result<usize, GraphError> {
-        self.graph.degree(node_id)
-    }
-
-    fn is_empty_node(&self, node_id: usize) -> Result<bool, GraphError> {
-        self.graph.is_empty_node(node_id)
-    }
-
-    fn has_edge(&self, source: usize, target: usize) -> Result<bool, GraphError> {
-        self.graph.has_edge(source, target)
-    }
-
-    fn replace_by_builder(&mut self, _builder: impl graph::Builder<Result = Self>) {
-        unimplemented!()
-    }
-}
-
-#[derive(Debug)]
-pub struct LabelIter<'a> {
-    set_iter: Iter<'a, usize>,
-}
-
-impl<'a> Iterator for LabelIter<'a> {
-    type Item = usize;
-
-    fn next(&mut self) -> Option<Self::Item> {
-        self.set_iter.next().copied()
-    }
-
-    fn size_hint(&self) -> (usize, Option<usize>) {
-        self.set_iter.size_hint()
-    }
-}
-
-impl<'a> ExactSizeIterator for LabelIter<'a> {
-    fn len(&self) -> usize {
-        self.set_iter.len()
-    }
-}
-
-impl<'a> From<Iter<'a, usize>> for LabelIter<'a> {
-    fn from(set_iter: Iter<'a, usize>) -> Self {
-        Self { set_iter }
-    }
-}
-
-impl<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> Forest<NodeLabel, EdgeLabel>
-    for DefaultForest<NodeLabel, EdgeLabel>
-{
-    type PluginIter<'a> = LabelIter<'a>
-    where
-        Self: 'a;
-
-    type PlugoutIter<'a> = LabelIter<'a>
-    where
-        Self: 'a;
-
-    fn plugins(&self) -> Self::PluginIter<'_> {
-        self.plugins.iter().into()
-    }
-
-    fn plugouts(&self) -> Self::PlugoutIter<'_> {
-        self.plugouts.iter().into()
-    }
-
-    fn plug(&mut self, other: &Self) -> Result<(), Error> {
-        // PLAN: Produce a BuilderMut, adjust the indices for edges,
-        // and then add edges between plugs.
-        //
-        // Since I cannot touch the underlying nodes directly, I have
-        // to add the nodes and edges individually.
-
-        todo!()
-    }
-
-    fn vertex_label(&self, node_id: usize) -> Result<Option<NodeLabel>, Error> {
-        if node_id >= self.nodes_len() {
-            return Err(Error::IndexOutOfBounds(node_id, self.nodes_len()));
-        }
-
-        Ok(self.vertex_labels.get(&node_id).copied())
-    }
-
-    fn edge_label(&self, source: usize, target: usize) -> Result<Option<EdgeLabel>, Error> {
-        if source >= self.nodes_len() {
-            return Err(Error::IndexOutOfBounds(source, self.nodes_len()));
-        }
-
-        if target >= self.nodes_len() {
-            return Err(Error::IndexOutOfBounds(target, self.nodes_len()));
-        }
-
-        Ok(self.edge_labels.get(&(source, target)).copied())
-    }
-}
+// #[derive(Debug, Clone)]
+// pub struct DefaultForest<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> {
+//     graph: ALGraph,
+//     vertex_labels: HashMap<usize, NodeLabel>,
+//     edge_labels: HashMap<(usize, usize), EdgeLabel>,
+//     plugins: HashSet<usize>,
+//     plugouts: HashSet<usize>,
+// }
diff --git a/forest/src/design.org b/forest/src/design.org
index 771ca4b..09db113 100644
--- a/forest/src/design.org
+++ b/forest/src/design.org
@@ -28,7 +28,7 @@ topic sooner or later, why not deal with it now?  ;P
   represent this alternation.  Packed nodes are not labelled.  They
   just serve the role of putting nodes together.
 
-* Some thoughts [1/3]
+* Some thoughts
 
 We do not need to attach forest fragments to nodes of nondeterministic
 finite automata: we just attach to them lists of grammar slots, which
@@ -44,23 +44,98 @@ non-terminals.
 
 Some caveats:
 
-- [X] Every node in the forest needs to know its parents.  This is
-  needed for "reductions".  That is, after we have parsed the entire
+- Every node in the forest needs to know its parents.  This is needed
+  for "reductions".  That is, after we have parsed the entire
   expansion for a non-terminal, we need to go back to where that
   non-terminal was and continue from there.
-- [ ] We need to record the expansions of those "virtual nodes".  That
-  is, the virtual nodes represent atomic languages such as [s]^{(t)}
-  where s is a non-terminal and t is a terminal.  To be more specific,
-  it represents the derivative of the left-linear closure of the
+- We need to record the expansions of those "virtual nodes".  That is,
+  the virtual nodes represent atomic languages such as [s]^{(t)} where s
+  is a non-terminal and t is a terminal.  To be more specific, it
+  represents the derivative of the left-linear closure of the
   non-terminal s with respect to the terminal t.  The left-linear
   closure of s is the set of all strings (consisting of terminals and
   non-terminals alike) that are derivable from s alone, without
   consuming any inputs, by expanding according to the grammar rules.
   This means that we need to know if which non-terminals were expanded
   in order to get to a state in [s]^{(t)}.
-- [ ] Each edge in the chain-rule machine needs to be labelled also
-  with a position in the forest.  This perfectly solves the problem of
-  those "plugs"!
+- Each edge in the chain-rule machine needs to be labelled also with a
+  position in the forest.  This perfectly solves the problem of those
+  "plugs"!
 
+* Formal Definition
 
+We need to figure out the definition of the forest.  That it to say,
+what will the resulting forest look like for a grammar.
 
+Moreover, we need to know how to correspond each step in the
+chain-rule machine with the definition of the forest.
+
+After these two steps, we can easily proceed with the construction of
+the chain-rule machine.
+
+** Axioms
+
+There are two *axioms* from which the definition of the forests
+follows.
+
+1. Each node has a unique label, given (principally) by three
+   components:
+   1) input range start
+   2) input range end
+   3) grammar label
+2. If different subtrees share the same node label as the root, a
+   "clone" of the root should be made, and there should be a
+   "representative" of all clones, which is treated as a normal node
+   with that label, and all clones are its children.
+
+The first axiom ensures that the size of the forest is bounded by the
+cube of \(n\), \(n\) is the length of the input sequence.  And the
+second axiom specifies what to do when subtrees share a parent.
+
+Since the clones are introduced only when subtrees share a parent,
+their number cannot exceed the number of nodes of a forest without
+clones.  This shows that adding clones does not affect the growth rate
+of the size of forests.
+
+A remark: the /clones/ are called /packed nodes/ in the traditional
+terminology, but the terminology of a clone makes more sense to me.
+
+** Correspondence with chain-rule machine
+
+Every edge in the chain-rule machine corresponds to an edge in the
+forest; denote this correspondence by \(f\).
+
+The chain-rule operation can be described as follows:
+
+1. Start with an edge \(e\) with children \(d_1, \ldots, d_n\) in the
+   chain-rule machine.
+2. Prepare a new forest fragment as follows.
+   1) For every child \(g\) of \(e\) in the atomic language, if \(g\)
+      is the terminal that appears as the current input \(t\), let the
+      new fragment be defined as the node moved by \(g\), alone.
+   2) If \(g\) is a non-terminal and its first-set contains \(t\),
+      then for every left-linearly closed child of \(g\) that is
+      labelled \(t\), denoted as \(h\), then let the fragment be
+      defined as the node moved by \(g\), with the pre-recorded
+      left-linear expansion information from \(g\) to \(h\) appended
+      as children.
+3. For \(i=1,\ldots,n\), consider the edge \(f(d_i)\) in the forest.
+   There are three cases:
+   1) If the next edge is empty, that means we have found something
+      totally new to add to the forest, so we just add that.
+   2) If the next edge after \(f(e)\) contains the new fragment as a
+      sub-tree already, this means the current branch has already been
+      explored before, and we have nothing else to do.
+   3) If the next edge is non-empty and does not match the new
+      fragment, this means we have a conflict with a previously found
+      branch.  We solve it simply by following the second axiom above:
+      we make the node that is the source of \(f(e)\) a clone, and add
+      the new fragment under a new clone.  Note that if the node is
+      already a clone, we just make a clone under the parent of that
+      clone.
+4. Update the correspondence \(f\) by updating \(f(g)\) and \(f(h)\)
+   accordingly.
+
+In this process we always follow the first axiom by ensuring that the
+labels of the forest are unique to each node, except for those clones,
+which are only created by following the second axiom.
diff --git a/forest/src/lib.rs b/forest/src/lib.rs
index 3925bd5..c2f4988 100644
--- a/forest/src/lib.rs
+++ b/forest/src/lib.rs
@@ -1,3 +1,4 @@
+#![warn(missing_docs)]
 //! This file defines the expected behaviours of forests, and provides
 //! a default implementation for forests.
 //!
@@ -10,12 +11,16 @@
 //! out-coming and in-coming plugs.  These plugs are used to join
 //! different fragments of forests together.
 
-use graph::{Graph, GraphLabel};
+use graph::{GraphLabel, LabelGraph, ParentsGraph};
 
 use core::fmt::Display;
 
+// TODO: move this to default
+
+/// The type of errors for forest operations.
 #[derive(Debug)]
 pub enum Error {
+    /// An index is out of bounds.
     IndexOutOfBounds(usize, usize),
 }
 
@@ -31,75 +36,52 @@ impl Display for Error {
 
 impl std::error::Error for Error {}
 
-/// A builder of a forest.
-pub trait ForestBuilder<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> {
-    /// The type of the resulting forest.
-    type Output: Forest<NodeLabel, EdgeLabel>;
-
-    /// Construct a new builder with only one node with the given
-    /// label.
-    fn new_leaf(label: NodeLabel) -> Self;
-
-    /// Add a child to the builder the given labels for the new node
-    /// and the added edge.
-    ///
-    /// All plug-out nodes within the builder should have a new child
-    /// with the specified labels, and hence multiple children might
-    /// be added, and the plug-out nodes should be modified
-    /// accordingly.
-    fn add_children(&mut self, vertex_label: NodeLabel, edge_labe: EdgeLabel);
-
-    /// Build the forest.
-    fn build(self) -> Self::Output;
-
-    /// Build the forest from a reference.
-    fn build_ref(&self) -> Self::Output;
-}
+// /// A builder of a forest.
+// pub trait ForestBuilder<NodeLabel: GraphLabel, EdgeLabel: GraphLabel> {
+//     /// The type of the resulting forest.
+//     type Output: Forest<NodeLabel, EdgeLabel>;
+
+//     /// Construct a new builder with only one node with the given
+//     /// label.
+//     fn new_leaf(label: NodeLabel) -> Self;
+
+//     /// Add a child to the builder the given labels for the new node
+//     /// and the added edge.
+//     ///
+//     /// All plug-out nodes within the builder should have a new child
+//     /// with the specified labels, and hence multiple children might
+//     /// be added, and the plug-out nodes should be modified
+//     /// accordingly.
+//     fn add_children(&mut self, vertex_label: NodeLabel, edge_labe: EdgeLabel);
+
+//     /// Build the forest.
+//     fn build(self) -> Self::Output;
+
+//     /// Build the forest from a reference.
+//     fn build_ref(&self) -> Self::Output;
+// }
+
+// FIXME: The trait should be re-designed.
 
 /// The expected behaviours of a forest.
 ///
-/// Note that it contains a "striped down" version of the labelled
-/// graphs.
-pub trait Forest<NodeLabel: GraphLabel, EdgeLabel: GraphLabel>: Graph {
-    /// Type of iterator of plug-in nodes.
-    type PluginIter<'a>: Iterator<Item = usize> + 'a
-    where
-        Self: 'a;
-
-    /// Type of iterator of plug-out nodes.
-    type PlugoutIter<'a>: Iterator<Item = usize> + 'a
-    where
-        Self: 'a;
-
-    /// Return the plug-in nodes
-    fn plugins(&self) -> Self::PluginIter<'_>;
-
-    /// Return the plug-out nodes
-    fn plugouts(&self) -> Self::PlugoutIter<'_>;
-
-    /// Plug another forest onto this forest.
-    ///
-    /// The plug-out nodes of this forest will be joined onto the
-    /// plug-in nodes of the joining forest.
-    ///
-    /// # Performance warning
-    ///
-    /// It is recommended to only call this function with a "small"
-    /// `other`, as this function might copy the whole graph
-    /// individually, node by node and edge by edge.
-    fn plug(&mut self, other: &Self) -> Result<(), Error>;
-
-    /// Return the vertex label.
-    ///
-    /// A vertex may not have labels.
-    fn vertex_label(&self, node_id: usize) -> Result<Option<NodeLabel>, Error>;
-
-    /// Return the edge label.
-    ///
-    /// An edge may have no labels.  If there is no edge from the
-    /// given source to the given target, then `Ok(None)` is returned
-    /// as well.
-    fn edge_label(&self, source: usize, target: usize) -> Result<Option<EdgeLabel>, Error>;
+/// Note that it requires only a subset of the functionalities of
+/// labelled graphs.
+pub trait Forest<T: GraphLabel>: ParentsGraph + LabelGraph<T> {
+    /// The type of errors for operations on the forest.
+    type Error: std::error::Error + From<graph::error::Error>;
+
+    /// Detect if the fragment is a prefix of the sub-forest rooted at
+    /// `node_id`.
+    fn is_prefix<F: AsRef<Self>>(&self, node_id: usize, fragment: F) -> Result<bool, Self::Error>;
+
+    /// Extend the forest by adjoining another forest at a given node.
+    fn plant<F: AsRef<Self>>(&mut self, node_id: usize, fragment: F) -> Result<(), Self::Error>;
+
+    /// Clone a node by making a new node and making all the nodes
+    /// that previously pointed to the old node now point to the new
+    /// node, and the new node points to the old node.
+    fn clone(&mut self, node_id: usize) -> Result<(), Self::Error>;
 }
 
 pub mod default;