//! Lazily compute the reverse control-flow graph for the MIR. use rustc_data_structures::stable_hasher::{HashStable, StableHasher}; use rustc_data_structures::sync::OnceCell; use rustc_index::vec::IndexVec; use rustc_serialize::{Decodable, Decoder, Encodable, Encoder}; use smallvec::SmallVec; use crate::mir::{BasicBlock, BasicBlockData}; // Typically 95%+ of basic blocks have 4 or fewer predecessors. pub type Predecessors = IndexVec>; #[derive(Clone, Debug)] pub(super) struct PredecessorCache { cache: OnceCell, } impl PredecessorCache { #[inline] pub(super) fn new() -> Self { PredecessorCache { cache: OnceCell::new() } } /// Invalidates the predecessor cache. #[inline] pub(super) fn invalidate(&mut self) { // Invalidating the predecessor cache requires mutating the MIR, which in turn requires a // unique reference (`&mut`) to the `mir::Body`. Because of this, we can assume that all // callers of `invalidate` have a unique reference to the MIR and thus to the predecessor // cache. This means we never need to do synchronization when `invalidate` is called, we can // simply reinitialize the `OnceCell`. self.cache = OnceCell::new(); } /// Returns the predecessor graph for this MIR. #[inline] pub(super) fn compute( &self, basic_blocks: &IndexVec>, ) -> &Predecessors { self.cache.get_or_init(|| { let mut preds = IndexVec::from_elem(SmallVec::new(), basic_blocks); for (bb, data) in basic_blocks.iter_enumerated() { if let Some(term) = &data.terminator { for succ in term.successors() { preds[succ].push(bb); } } } preds }) } } impl Encodable for PredecessorCache { #[inline] fn encode(&self, _s: &mut S) {} } impl Decodable for PredecessorCache { #[inline] fn decode(_: &mut D) -> Self { Self::new() } } impl HashStable for PredecessorCache { #[inline] fn hash_stable(&self, _: &mut CTX, _: &mut StableHasher) { // do nothing } } TrivialTypeTraversalAndLiftImpls! { PredecessorCache, }