cranelift_isle/overlap.rs
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//! Overlap detection for rules in ISLE.
use std::collections::hash_map::Entry;
use std::collections::{HashMap, HashSet};
use crate::error::{self, Error, Span};
use crate::lexer::Pos;
use crate::sema::{TermEnv, TermId, TermKind, TypeEnv};
use crate::trie_again;
/// Check for overlap.
pub fn check(
tyenv: &TypeEnv,
termenv: &TermEnv,
) -> Result<Vec<(TermId, trie_again::RuleSet)>, error::Errors> {
let (terms, mut errors) = trie_again::build(termenv);
errors.append(&mut check_overlaps(&terms, termenv).report());
if errors.is_empty() {
Ok(terms)
} else {
Err(error::Errors {
errors,
filenames: tyenv.filenames.clone(),
file_texts: tyenv.file_texts.clone(),
})
}
}
/// A graph of rules that overlap in the ISLE source. The edges are undirected.
#[derive(Default)]
struct Errors {
/// Edges between rules indicating overlap.
nodes: HashMap<Pos, HashSet<Pos>>,
/// For each (mask, shadowed) pair, every rule in `shadowed` is unmatchable because `mask` will
/// always match first.
shadowed: HashMap<Pos, Vec<Pos>>,
}
impl Errors {
/// Condense the overlap information down into individual errors. We iteratively remove the
/// nodes from the graph with the highest degree, reporting errors for them and their direct
/// connections. The goal with reporting errors this way is to prefer reporting rules that
/// overlap with many others first, and then report other more targeted overlaps later.
fn report(mut self) -> Vec<Error> {
let mut errors = Vec::new();
while let Some((&pos, _)) = self
.nodes
.iter()
.max_by_key(|(pos, edges)| (edges.len(), *pos))
{
let node = self.nodes.remove(&pos).unwrap();
for other in node.iter() {
if let Entry::Occupied(mut entry) = self.nodes.entry(*other) {
let back_edges = entry.get_mut();
back_edges.remove(&pos);
if back_edges.is_empty() {
entry.remove();
}
}
}
// build the real error
let mut rules = vec![Span::new_single(pos)];
rules.extend(node.into_iter().map(Span::new_single));
errors.push(Error::OverlapError {
msg: String::from("rules are overlapping"),
rules,
});
}
errors.extend(
self.shadowed
.into_iter()
.map(|(mask, shadowed)| Error::ShadowedError {
shadowed: shadowed.into_iter().map(Span::new_single).collect(),
mask: Span::new_single(mask),
}),
);
errors.sort_by_key(|err| match err {
Error::ShadowedError { mask, .. } => mask.from,
Error::OverlapError { rules, .. } => rules[0].from,
_ => Pos::default(),
});
errors
}
fn check_pair(&mut self, a: &trie_again::Rule, b: &trie_again::Rule) {
if let trie_again::Overlap::Yes { subset } = a.may_overlap(b) {
if a.prio == b.prio {
// edges are undirected
self.nodes.entry(a.pos).or_default().insert(b.pos);
self.nodes.entry(b.pos).or_default().insert(a.pos);
} else if subset {
// One rule's constraints are a subset of the other's, or they're equal.
// This is fine as long as the higher-priority rule has more constraints.
let (lo, hi) = if a.prio < b.prio { (a, b) } else { (b, a) };
if hi.total_constraints() <= lo.total_constraints() {
// Otherwise, the lower-priority rule can never match.
self.shadowed.entry(hi.pos).or_default().push(lo.pos);
}
}
}
}
}
/// Determine if any rules overlap in the input that they accept. This checks every unique pair of
/// rules, as checking rules in aggregate tends to suffer from exponential explosion in the
/// presence of wildcard patterns.
fn check_overlaps(terms: &[(TermId, trie_again::RuleSet)], env: &TermEnv) -> Errors {
let mut errs = Errors::default();
for (tid, ruleset) in terms {
let is_multi_ctor = match &env.terms[tid.index()].kind {
TermKind::Decl { flags, .. } => flags.multi,
_ => false,
};
if is_multi_ctor {
// Rules for multi-constructors are not checked for
// overlap: the ctor returns *every* match, not just
// the first or highest-priority one, so overlap does
// not actually affect the results.
continue;
}
let mut cursor = ruleset.rules.iter();
while let Some(left) = cursor.next() {
for right in cursor.as_slice() {
errs.check_pair(left, right);
}
}
}
errs
}