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|
//! This file provides a default implementation of the
//! [`Chain`][crate::Chain] trait.
//!
//! The reason for using a trait is that I might want to experiment
//! with different implementation ideas in the future, and this
//! modular design makes that easy.
use super::*;
use crate::atom::{Atom, DefaultAtom};
use core::fmt::Display;
use forest::{default::DefaultForest, Forest};
use grammar::{Error as GrammarError, GrammarLabel, GrammarLabelType, TNT};
#[allow(unused_imports)]
use graph::{
labelled::DLGBuilder, Builder, DLGraph, Graph, LabelExtGraph, LabelGraph, ParentsGraph,
};
use std::collections::{HashMap as Map, TryReserveError};
/// The errors related to taking derivatives by chain rule.
#[non_exhaustive]
#[derive(Debug)]
pub enum Error {
/// General error for indices out of bounds.
IndexOutOfBounds(usize, usize),
/// The forest encounters a duplicate node, for some reason.
DuplicateNode(usize),
/// The chain rule machine encounters a duplicate edge, for some
/// reason.
DuplicateEdge(usize, usize),
/// A node has no labels while it is required to have one.
NodeNoLabel(usize),
/// Reserving memory fails.
CannotReserve(TryReserveError),
/// An invalid situation happens.
Invalid,
}
impl Display for Error {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
match self {
Self::IndexOutOfBounds(index, bound) => write!(f, "index {index} out of bound {bound}"),
Self::DuplicateNode(n) => write!(f, "the forest has a node {n} with a duplicate label"),
Self::DuplicateEdge(source, target) => write!(
f,
"the forest has a duplicate edge from {source} to {target}"
),
Self::NodeNoLabel(n) => write!(f, "node {n} has no labels while it should have one"),
Self::CannotReserve(e) => write!(f, "cannot reserve memory: {e}"),
Self::Invalid => write!(f, "invalid"),
}
}
}
impl std::error::Error for Error {}
impl From<GError> for Error {
fn from(value: GError) -> Self {
match value {
GError::IndexOutOfBounds(index, bound) => Self::IndexOutOfBounds(index, bound),
GError::DuplicatedNode(n) => Self::DuplicateNode(n),
GError::DuplicatedEdge(source, target) => Self::DuplicateEdge(source, target),
_ => Self::Invalid,
}
}
}
impl From<ForestError> for Error {
fn from(e: ForestError) -> Self {
match e {
ForestError::IndexOutOfBounds(index, bound) => Error::IndexOutOfBounds(index, bound),
ForestError::DuplicatedNode(n) => Error::DuplicateNode(n),
ForestError::InvalidGraphError(ge) => ge.into(),
ForestError::NodeNoLabel(n) => Error::NodeNoLabel(n),
}
}
}
impl From<TryReserveError> for Error {
fn from(value: TryReserveError) -> Self {
Self::CannotReserve(value)
}
}
/// The type of an index into an element in [`DerIter`].
#[derive(Debug, Copy, Clone)]
enum DerIterIndex {
Single(usize),
Map(usize),
}
impl Default for DerIterIndex {
fn default() -> Self {
Self::Map(0)
}
}
/// A complex type used for storing values of edges with two layers.
type SecondTypeValue = (Parent, bool, Vec<(Edge, usize)>);
/// An iterator of TwoLayers.
#[derive(Debug, Default)]
pub struct DerIter {
/// Stores edges of only one layer.
singles: Vec<(Edge, usize)>,
/// Stores edges with two layers. They are grouped by their
/// labels of the second layer.
///
/// The values are tuples (forest_source, accepting, edges), where
/// the edges are the grouped edges of the first layer and the
/// destination.
seconds: Map<usize, SecondTypeValue>,
/// We want to iterate the elements of the map, for which purpose
/// we need an array. Since hashmaps provide no arrays, we keep
/// an array of keys for iteration purposes.
second_array: Vec<usize>,
/// The index of the current element, either in `second_array` or
/// in `singles` .
index: DerIterIndex,
}
impl DerIter {
fn add_second_layer(
&mut self,
label: usize,
forest_source: Parent,
accepting: bool,
edges: Vec<(Edge, usize)>,
) {
if let Some((_, _, vec)) = self.seconds.get_mut(&label) {
vec.extend(edges);
} else {
self.seconds
.insert(label, (forest_source, accepting, edges));
self.second_array.push(label);
}
}
}
impl Iterator for DerIter {
type Item = TwoLayers;
fn next(&mut self) -> Option<Self::Item> {
// We iterate through two layered edges first.
match self.index {
DerIterIndex::Map(index) => {
if let Some(key) = self.second_array.get(index) {
if let Some((forest_source, accepting, edges)) = self.seconds.remove(key) {
self.index = DerIterIndex::Map(index + 1);
Some(TwoLayers::Two(*key, forest_source, accepting, edges))
} else {
// this should not happen
println!("a key does not exist in the hashmap: something is wrong when taking derivatives");
None
}
} else {
self.index = DerIterIndex::Single(0);
if let Some((edge, to)) = self.singles.first() {
self.index = DerIterIndex::Single(1);
Some(TwoLayers::One(*edge, *to))
} else {
None
}
}
}
DerIterIndex::Single(index) => {
if let Some((edge, to)) = self.singles.get(index) {
self.index = DerIterIndex::Single(index + 1);
Some(TwoLayers::One(*edge, *to))
} else {
None
}
}
}
}
}
/// A default implementation for the [`Chain`] trait.
#[derive(Debug, Clone, Default)]
pub struct DefaultChain {
graph: DLGraph<Edge>,
atom: DefaultAtom,
current: usize,
history: Vec<usize>,
forest: DefaultForest<GrammarLabel>,
accepting_vec: Vec<bool>,
}
impl DefaultChain {
/// Return the current node.
#[inline]
pub fn current(&self) -> usize {
self.current
}
/// Return the complete slice of histories.
#[inline]
pub fn history(&self) -> &[usize] {
self.history.as_ref()
}
/// Return a reference to the associated forest.
#[inline]
pub fn forest(&self) -> &DefaultForest<GrammarLabel> {
&self.forest
}
/// Print the rule positions of the labels.
pub fn print_rule_positions(&self) -> Result<(), Box<dyn std::error::Error>> {
let mut labels = std::collections::HashSet::<usize>::default();
for node in 0..self.graph.nodes_len() {
labels.extend(self.graph.labels_of(node)?.map(|(label, _)| label.label));
}
for label in labels.into_iter() {
println!("{}", self.atom.rule_pos_string(label)?);
}
Ok(())
}
}
impl Graph for DefaultChain {
type Iter<'a> = <DLGraph<Edge> as Graph>::Iter<'a>
where
Self: 'a;
#[inline]
fn is_empty(&self) -> bool {
self.graph.is_empty()
}
#[inline]
fn nodes_len(&self) -> usize {
self.graph.nodes_len()
}
#[inline]
fn edges_len(&self) -> Option<usize> {
self.graph.edges_len()
}
#[inline]
fn children_of(&self, node_id: usize) -> Result<Self::Iter<'_>, GError> {
self.graph.children_of(node_id)
}
#[inline]
fn degree(&self, node_id: usize) -> Result<usize, GError> {
self.graph.degree(node_id)
}
#[inline]
fn is_empty_node(&self, node_id: usize) -> Result<bool, GError> {
self.graph.is_empty_node(node_id)
}
#[inline]
fn has_edge(&self, source: usize, target: usize) -> Result<bool, GError> {
self.graph.has_edge(source, target)
}
fn replace_by_builder(&mut self, _builder: impl graph::Builder<Result = Self>) {
unimplemented!("I shall refactor this")
}
}
impl LabelGraph<Edge> for DefaultChain {
type Iter<'a> = <DLGraph<Edge> as LabelGraph<Edge>>::Iter<'a>
where
Self: 'a;
type LabelIter<'a> = <DLGraph<Edge> as LabelGraph<Edge>>::LabelIter<'a>
where
Self: 'a,
Edge: 'a;
type EdgeLabelIter<'a> = <DLGraph<Edge> as LabelGraph<Edge>>::EdgeLabelIter<'a>
where
Self: 'a,
Edge: 'a;
#[inline]
fn edge_label(&self, source: usize, target: usize) -> Result<Self::EdgeLabelIter<'_>, GError> {
self.graph.edge_label(source, target)
}
#[inline]
fn find_children_with_label(
&self,
node_id: usize,
label: &Edge,
) -> Result<<Self as LabelGraph<Edge>>::Iter<'_>, GError> {
self.graph.find_children_with_label(node_id, label)
}
#[inline]
fn labels_of(&self, node_id: usize) -> Result<Self::LabelIter<'_>, GError> {
self.graph.labels_of(node_id)
}
#[inline]
fn has_edge_label(&self, node_id: usize, label: &Edge, target: usize) -> Result<bool, GError> {
self.graph.has_edge_label(node_id, label, target)
}
}
impl LabelExtGraph<Edge> for DefaultChain {
#[inline]
fn extend(&mut self, edges: impl IntoIterator<Item = (Edge, usize)>) -> Result<usize, GError> {
let new = self.graph.extend(edges)?;
let accepting_len = self.accepting_vec.len();
if self.accepting_vec.get(new).is_none() {
// assert it can only grow by one node at a time.
#[cfg(debug_assertions)]
assert_eq!(new, accepting_len);
let mut updated = false;
for (label, child_iter) in self.graph.labels_of(new)? {
let old_accepting = {
let mut result = false;
for child in child_iter {
if *self
.accepting_vec
.get(child)
.ok_or(GError::IndexOutOfBounds(child, accepting_len))?
{
result = true;
break;
}
}
result
};
if !old_accepting {
self.accepting_vec.push(false);
updated = true;
break;
}
if label.is_accepting() {
self.accepting_vec.push(true);
updated = true;
break;
}
}
if !updated {
self.accepting_vec.push(false);
}
}
Ok(new)
}
}
impl Chain for DefaultChain {
type Error = Error;
type Atom = DefaultAtom;
fn unit(atom: Self::Atom) -> Result<Self, Self::Error> {
let mut builder: DLGBuilder<Edge> = Default::default();
let root = builder.add_vertex();
let first = builder.add_vertex();
let empty_state = atom.empty();
let initial_nullable = atom
.is_nullable(0)
.map_err(|_| Error::IndexOutOfBounds(0, atom.non_num()))?;
builder.add_edge(
first,
root,
Edge::new(empty_state, Parent::new(0, 0), initial_nullable),
)?;
let graph = builder.build();
let forest =
DefaultForest::new_leaf(GrammarLabel::new(GrammarLabelType::TNT(TNT::Non(0)), 0));
#[cfg(debug_assertions)]
assert_eq!(forest.root(), Some(0));
let current = 1;
let history = Vec::new();
let accepting_vec = vec![true, initial_nullable];
Ok(Self {
graph,
atom,
current,
history,
forest,
accepting_vec,
})
}
fn epsilon(&self) -> Result<bool, Self::Error> {
self.accepting_vec
.get(self.current)
.copied()
.ok_or(Error::IndexOutOfBounds(
self.current,
self.accepting_vec.len(),
))
}
fn update_history(&mut self, new: usize) {
debug_assert!(new < self.graph.nodes_len());
self.history.push(self.current);
self.current = new;
}
type DerIter = DerIter;
fn derive(&mut self, t: usize, _pos: usize) -> Result<Self::DerIter, Self::Error> {
use TNT::*;
/// 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)
}
_ => panic!("wrong error kind"),
}
}
/// A helper function to generate edges to join.
///
/// It first checks if the base edge is accepting. If yes,
/// then pull in the children of the target.
///
/// Then check if the label of the base edge has children. If
/// no, then do not add this base edge itself.
///
/// The generated edges will be pushed to `output` directly,
/// to save some allocations.
// TODO: Handle forests as well.
fn generate_edges(
chain: &DefaultChain,
child_iter: impl Iterator<Item = usize> + ExactSizeIterator + Clone,
atom_child_iter: impl Iterator<Item = usize> + Clone,
mut output: impl AsMut<Vec<(Edge, usize)>>,
) -> Result<(), Error> {
// First check the values from iterators are all valid.
let graph_len = chain.graph.nodes_len();
let atom_len = chain.atom.nodes_len();
for child in child_iter.clone() {
if !chain.graph.has_node(child) {
return Err(Error::IndexOutOfBounds(child, graph_len));
}
}
for atom_child in atom_child_iter.clone() {
if !chain.atom.has_node(atom_child) {
return Err(Error::IndexOutOfBounds(atom_child, atom_len));
}
}
// From now on the nodes are all valid, so we can just
// call `unwrap`.
// Then calculate the number of edges to append, to avoid
// repeated allocations
let mut num = 0usize;
let child_iter_total_degree = child_iter
.clone()
.map(|child| chain.graph.degree(child).unwrap())
.sum::<usize>();
for atom_child in atom_child_iter.clone() {
let atom_child_accepting = chain.atom.is_accepting(atom_child).unwrap();
let atom_child_empty_node = chain.atom.is_empty_node(atom_child).unwrap();
if !atom_child_empty_node {
num += child_iter.len();
}
if atom_child_accepting {
num += child_iter_total_degree;
}
}
let num = num;
let output = output.as_mut();
output.try_reserve(num)?;
// now push into output
let parent = Parent::new(0, 0);
for atom_child in atom_child_iter {
let atom_child_accepting = chain.atom.is_accepting(atom_child).unwrap();
let atom_child_empty_node = chain.atom.is_empty_node(atom_child).unwrap();
let edge = Edge::new(atom_child, parent, atom_child_accepting);
if !atom_child_empty_node {
output.extend(child_iter.clone().map(|child| (edge, child)));
}
if atom_child_accepting {
for child in child_iter.clone() {
for (child_label, child_child) in chain.graph.labels_of(child).unwrap() {
output.extend(child_child.map(|target| (*child_label, target)));
}
}
}
}
Ok(())
}
let mut der_iter = DerIter::default();
for (label, child_iter) in self.graph.labels_of(self.current)? {
for (atom_label, atom_child_iter) in self.atom.labels_of(label.label())? {
if atom_label.is_left_p() {
// We do not consider left-linearly expanded
// children in the first layer.
continue;
}
match *atom_label.get_value() {
Some(Ter(ter)) if ter == t => {
generate_edges(
self,
child_iter.clone(),
atom_child_iter.clone(),
&mut der_iter.singles,
)?;
}
Some(Non(non)) => {
let virtual_node = self
.atom
.atom(non, t)
.map_err(index_out_of_bounds_conversion)?;
if let Some(virtual_node) = virtual_node {
let accepting = self
.atom
.is_accepting(virtual_node)
.map_err(index_out_of_bounds_conversion)?;
let mut new_edges = Vec::new();
generate_edges(
self,
child_iter.clone(),
atom_child_iter.clone(),
&mut new_edges,
)?;
if accepting {
der_iter.singles.extend(new_edges.clone());
}
let parent = Parent::new(0, 0);
if !self.atom.is_empty_node(virtual_node).unwrap() {
der_iter.add_second_layer(
virtual_node,
parent,
accepting,
new_edges,
);
// account for atom_children without
// children.
for atom_child in atom_child_iter {
// this has been checked in
// `generate_edges`
if self.atom.is_empty_node(atom_child).unwrap() {
der_iter.singles.extend(child_iter.clone().map(|child| {
(Edge::new(virtual_node, parent, accepting), child)
}));
}
}
} else {
for atom_child in atom_child_iter {
// this has been checked in
// `generate_edges`
if self.atom.is_empty_node(atom_child).unwrap() {
// flat flat map, hmm...
der_iter.singles.extend(child_iter.clone().flat_map(
|child| {
self.graph.labels_of(child).unwrap().flat_map(
|(child_label, child_child_iter)| {
child_child_iter.map(|child_child| {
(*child_label, child_child)
})
},
)
},
));
}
}
}
}
}
_ => {
continue;
}
}
}
}
Ok(der_iter)
}
}
#[cfg(test)]
mod test_der_iter {
use super::*;
#[test]
fn test() -> Result<(), Box<dyn std::error::Error>> {
let mut der_iter = DerIter::default();
let parent = Parent::new(0, 0);
der_iter.singles.push((Edge::new(0, parent, true), 0));
der_iter.singles.push((Edge::new(1, parent, true), 0));
der_iter.singles.push((Edge::new(2, parent, true), 0));
der_iter.add_second_layer(3, parent, true, vec![(Edge::new(4, parent, true), 1)]);
der_iter.add_second_layer(6, parent, true, vec![(Edge::new(5, parent, true), 1)]);
// add an entry with a repeated label
der_iter.add_second_layer(3, parent, true, vec![(Edge::new(7, parent, true), 2)]);
assert_eq!(
der_iter.next(),
Some(TwoLayers::Two(
3,
parent,
true,
vec![
(Edge::new(4, parent, true), 1),
(Edge::new(7, parent, true), 2)
]
))
);
assert_eq!(
der_iter.next(),
Some(TwoLayers::Two(
6,
parent,
true,
vec![(Edge::new(5, parent, true), 1)]
))
);
assert_eq!(
der_iter.next(),
Some(TwoLayers::One(Edge::new(0, parent, true), 0))
);
assert_eq!(
der_iter.next(),
Some(TwoLayers::One(Edge::new(1, parent, true), 0))
);
assert_eq!(
der_iter.next(),
Some(TwoLayers::One(Edge::new(2, parent, true), 0))
);
assert_eq!(der_iter.next(), None);
assert_eq!(der_iter.next(), None);
Ok(())
}
}
#[cfg(test)]
mod test_chain {
use super::*;
use grammar::test_grammar_helper::*;
#[test]
fn base_test() -> Result<(), Box<dyn std::error::Error>> {
let grammar = new_notes_grammar()?;
let atom = DefaultAtom::from_grammar(grammar)?;
let mut chain = DefaultChain::unit(atom)?;
chain.chain(3, 00)?;
chain.chain(1, 01)?;
chain.chain(2, 02)?;
chain.chain(2, 03)?;
chain.chain(2, 04)?;
chain.chain(0, 05)?;
chain.chain(5, 06)?;
chain.chain(1, 07)?;
chain.chain(6, 08)?;
chain.chain(6, 09)?;
chain.chain(6, 10)?;
chain.chain(0, 11)?;
chain.chain(0, 12)?;
assert!(matches!(chain.epsilon(), Ok(true)));
#[cfg(feature = "test-print-viz")]
{
chain.graph.print_viz("chain.gv")?;
chain.atom.print_nfa("nfa.gv")?;
}
Ok(())
}
#[test]
fn test_speed() -> Result<(), Box<dyn std::error::Error>> {
let grammar = new_notes_grammar_no_regexp()?;
println!("grammar: {grammar}");
let atom = DefaultAtom::from_grammar(grammar)?;
let mut chain = DefaultChain::unit(atom)?;
let input_template = vec![3, 1, 2, 2, 2, 0, 5, 1, 6, 6, 6, 0, 0];
let repeat_times = {
let mut result = 1;
for arg in std::env::args() {
let parse_as_digit: Result<usize, _> = arg.parse();
// just use the first number in the arguments
if let Ok(parse_result) = parse_as_digit {
result = parse_result;
break;
}
}
result
};
println!("repeating {repeat_times} times");
let input = {
let mut result = Vec::with_capacity(input_template.len() * repeat_times);
for _ in 0..repeat_times {
result.extend(input_template.iter().copied());
}
result
};
let start = std::time::Instant::now();
for (index, t) in input.iter().copied().enumerate() {
chain.chain(t, index)?;
}
let elapsed = start.elapsed();
// assert!(matches!(chain.epsilon(), Ok(true)));
dbg!(elapsed);
dbg!(chain.current());
assert_eq!(input.len(), chain.history().len());
if std::fs::metadata("output/history").is_ok() {
std::fs::remove_file("output/history")?;
}
let mut history_file = std::fs::OpenOptions::new()
.create(true)
.write(true)
.open("output/history")?;
use std::fmt::Write;
use std::io::Write as IOWrite;
let mut log_string = String::new();
writeln!(&mut log_string, "index: terminal, history")?;
for (index, t) in input.iter().copied().enumerate().take(input.len() - 1) {
writeln!(
&mut log_string,
"{index}: {t}, {}",
chain.history().get(index).unwrap()
)?;
}
println!("Successfully logged to output/history");
history_file.write_all(log_string.as_bytes())?;
#[cfg(feature = "test-print-viz")]
{
chain.graph.print_viz("chain.gv")?;
chain.atom.print_nfa("nfa.gv")?;
}
Ok(())
}
}
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