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//! Finding the dominators in a control-flow graph.
//!
//! Algorithm based on Loukas Georgiadis,
//! "Linear-Time Algorithms for Dominators and Related Problems",
//! <ftp://ftp.cs.princeton.edu/techreports/2005/737.pdf>
//!
//! Additionally useful is the original Lengauer-Tarjan paper on this subject,
//! "A Fast Algorithm for Finding Dominators in a Flowgraph"
//! Thomas Lengauer and Robert Endre Tarjan.
//! <https://www.cs.princeton.edu/courses/archive/spr03/cs423/download/dominators.pdf>
use super::ControlFlowGraph;
use rustc_index::vec::{Idx, IndexVec};
use std::cmp::Ordering;
#[cfg(test)]
mod tests;
struct PreOrderFrame<Iter> {
pre_order_idx: PreorderIndex,
iter: Iter,
}
rustc_index::newtype_index! {
struct PreorderIndex { .. }
}
pub fn dominators<G: ControlFlowGraph>(graph: G) -> Dominators<G::Node> {
// compute the post order index (rank) for each node
let mut post_order_rank = IndexVec::from_elem_n(0, graph.num_nodes());
// We allocate capacity for the full set of nodes, because most of the time
// most of the nodes *are* reachable.
let mut parent: IndexVec<PreorderIndex, PreorderIndex> =
IndexVec::with_capacity(graph.num_nodes());
let mut stack = vec![PreOrderFrame {
pre_order_idx: PreorderIndex::new(0),
iter: graph.successors(graph.start_node()),
}];
let mut pre_order_to_real: IndexVec<PreorderIndex, G::Node> =
IndexVec::with_capacity(graph.num_nodes());
let mut real_to_pre_order: IndexVec<G::Node, Option<PreorderIndex>> =
IndexVec::from_elem_n(None, graph.num_nodes());
pre_order_to_real.push(graph.start_node());
parent.push(PreorderIndex::new(0)); // the parent of the root node is the root for now.
real_to_pre_order[graph.start_node()] = Some(PreorderIndex::new(0));
let mut post_order_idx = 0;
// Traverse the graph, collecting a number of things:
//
// * Preorder mapping (to it, and back to the actual ordering)
// * Postorder mapping (used exclusively for rank_partial_cmp on the final product)
// * Parents for each vertex in the preorder tree
//
// These are all done here rather than through one of the 'standard'
// graph traversals to help make this fast.
'recurse: while let Some(frame) = stack.last_mut() {
while let Some(successor) = frame.iter.next() {
if real_to_pre_order[successor].is_none() {
let pre_order_idx = pre_order_to_real.push(successor);
real_to_pre_order[successor] = Some(pre_order_idx);
parent.push(frame.pre_order_idx);
stack.push(PreOrderFrame { pre_order_idx, iter: graph.successors(successor) });
continue 'recurse;
}
}
post_order_rank[pre_order_to_real[frame.pre_order_idx]] = post_order_idx;
post_order_idx += 1;
stack.pop();
}
let reachable_vertices = pre_order_to_real.len();
let mut idom = IndexVec::from_elem_n(PreorderIndex::new(0), reachable_vertices);
let mut semi = IndexVec::from_fn_n(std::convert::identity, reachable_vertices);
let mut label = semi.clone();
let mut bucket = IndexVec::from_elem_n(vec![], reachable_vertices);
let mut lastlinked = None;
// We loop over vertices in reverse preorder. This implements the pseudocode
// of the simple Lengauer-Tarjan algorithm. A few key facts are noted here
// which are helpful for understanding the code (full proofs and such are
// found in various papers, including one cited at the top of this file).
//
// For each vertex w (which is not the root),
// * semi[w] is a proper ancestor of the vertex w (i.e., semi[w] != w)
// * idom[w] is an ancestor of semi[w] (i.e., idom[w] may equal semi[w])
//
// An immediate dominator of w (idom[w]) is a vertex v where v dominates w
// and every other dominator of w dominates v. (Every vertex except the root has
// a unique immediate dominator.)
//
// A semidominator for a given vertex w (semi[w]) is the vertex v with minimum
// preorder number such that there exists a path from v to w in which all elements (other than w) have
// preorder numbers greater than w (i.e., this path is not the tree path to
// w).
for w in (PreorderIndex::new(1)..PreorderIndex::new(reachable_vertices)).rev() {
// Optimization: process buckets just once, at the start of the
// iteration. Do not explicitly empty the bucket (even though it will
// not be used again), to save some instructions.
//
// The bucket here contains the vertices whose semidominator is the
// vertex w, which we are guaranteed to have found: all vertices who can
// be semidominated by w must have a preorder number exceeding w, so
// they have been placed in the bucket.
//
// We compute a partial set of immediate dominators here.
let z = parent[w];
for &v in bucket[z].iter() {
// This uses the result of Lemma 5 from section 2 from the original
// 1979 paper, to compute either the immediate or relative dominator
// for a given vertex v.
//
// eval returns a vertex y, for which semi[y] is minimum among
// vertices semi[v] +> y *> v. Note that semi[v] = z as we're in the
// z bucket.
//
// Given such a vertex y, semi[y] <= semi[v] and idom[y] = idom[v].
// If semi[y] = semi[v], though, idom[v] = semi[v].
//
// Using this, we can either set idom[v] to be:
// * semi[v] (i.e. z), if semi[y] is z
// * idom[y], otherwise
//
// We don't directly set to idom[y] though as it's not necessarily
// known yet. The second preorder traversal will cleanup by updating
// the idom for any that were missed in this pass.
let y = eval(&mut parent, lastlinked, &semi, &mut label, v);
idom[v] = if semi[y] < z { y } else { z };
}
// This loop computes the semi[w] for w.
semi[w] = w;
for v in graph.predecessors(pre_order_to_real[w]) {
let v = real_to_pre_order[v].unwrap();
// eval returns a vertex x from which semi[x] is minimum among
// vertices semi[v] +> x *> v.
//
// From Lemma 4 from section 2, we know that the semidominator of a
// vertex w is the minimum (by preorder number) vertex of the
// following:
//
// * direct predecessors of w with preorder number less than w
// * semidominators of u such that u > w and there exists (v, w)
// such that u *> v
//
// This loop therefore identifies such a minima. Note that any
// semidominator path to w must have all but the first vertex go
// through vertices numbered greater than w, so the reverse preorder
// traversal we are using guarantees that all of the information we
// might need is available at this point.
//
// The eval call will give us semi[x], which is either:
//
// * v itself, if v has not yet been processed
// * A possible 'best' semidominator for w.
let x = eval(&mut parent, lastlinked, &semi, &mut label, v);
semi[w] = std::cmp::min(semi[w], semi[x]);
}
// semi[w] is now semidominator(w) and won't change any more.
// Optimization: Do not insert into buckets if parent[w] = semi[w], as
// we then immediately know the idom.
//
// If we don't yet know the idom directly, then push this vertex into
// our semidominator's bucket, where it will get processed at a later
// stage to compute its immediate dominator.
if parent[w] != semi[w] {
bucket[semi[w]].push(w);
} else {
idom[w] = parent[w];
}
// Optimization: We share the parent array between processed and not
// processed elements; lastlinked represents the divider.
lastlinked = Some(w);
}
// Finalize the idoms for any that were not fully settable during initial
// traversal.
//
// If idom[w] != semi[w] then we know that we've stored vertex y from above
// into idom[w]. It is known to be our 'relative dominator', which means
// that it's one of w's ancestors and has the same immediate dominator as w,
// so use that idom.
for w in PreorderIndex::new(1)..PreorderIndex::new(reachable_vertices) {
if idom[w] != semi[w] {
idom[w] = idom[idom[w]];
}
}
let mut immediate_dominators = IndexVec::from_elem_n(None, graph.num_nodes());
for (idx, node) in pre_order_to_real.iter_enumerated() {
immediate_dominators[*node] = Some(pre_order_to_real[idom[idx]]);
}
Dominators { post_order_rank, immediate_dominators }
}
/// Evaluate the link-eval virtual forest, providing the currently minimum semi
/// value for the passed `node` (which may be itself).
///
/// This maintains that for every vertex v, `label[v]` is such that:
///
/// ```text
/// semi[eval(v)] = min { semi[label[u]] | root_in_forest(v) +> u *> v }
/// ```
///
/// where `+>` is a proper ancestor and `*>` is just an ancestor.
#[inline]
fn eval(
ancestor: &mut IndexVec<PreorderIndex, PreorderIndex>,
lastlinked: Option<PreorderIndex>,
semi: &IndexVec<PreorderIndex, PreorderIndex>,
label: &mut IndexVec<PreorderIndex, PreorderIndex>,
node: PreorderIndex,
) -> PreorderIndex {
if is_processed(node, lastlinked) {
compress(ancestor, lastlinked, semi, label, node);
label[node]
} else {
node
}
}
#[inline]
fn is_processed(v: PreorderIndex, lastlinked: Option<PreorderIndex>) -> bool {
if let Some(ll) = lastlinked { v >= ll } else { false }
}
#[inline]
fn compress(
ancestor: &mut IndexVec<PreorderIndex, PreorderIndex>,
lastlinked: Option<PreorderIndex>,
semi: &IndexVec<PreorderIndex, PreorderIndex>,
label: &mut IndexVec<PreorderIndex, PreorderIndex>,
v: PreorderIndex,
) {
assert!(is_processed(v, lastlinked));
// Compute the processed list of ancestors
//
// We use a heap stack here to avoid recursing too deeply, exhausting the
// stack space.
let mut stack: smallvec::SmallVec<[_; 8]> = smallvec::smallvec![v];
let mut u = ancestor[v];
while is_processed(u, lastlinked) {
stack.push(u);
u = ancestor[u];
}
// Then in reverse order, popping the stack
for &[v, u] in stack.array_windows().rev() {
if semi[label[u]] < semi[label[v]] {
label[v] = label[u];
}
ancestor[v] = ancestor[u];
}
}
#[derive(Clone, Debug)]
pub struct Dominators<N: Idx> {
post_order_rank: IndexVec<N, usize>,
immediate_dominators: IndexVec<N, Option<N>>,
}
impl<Node: Idx> Dominators<Node> {
pub fn dummy() -> Self {
Self { post_order_rank: IndexVec::new(), immediate_dominators: IndexVec::new() }
}
pub fn is_reachable(&self, node: Node) -> bool {
self.immediate_dominators[node].is_some()
}
pub fn immediate_dominator(&self, node: Node) -> Node {
assert!(self.is_reachable(node), "node {:?} is not reachable", node);
self.immediate_dominators[node].unwrap()
}
pub fn dominators(&self, node: Node) -> Iter<'_, Node> {
assert!(self.is_reachable(node), "node {:?} is not reachable", node);
Iter { dominators: self, node: Some(node) }
}
pub fn is_dominated_by(&self, node: Node, dom: Node) -> bool {
// FIXME -- could be optimized by using post-order-rank
self.dominators(node).any(|n| n == dom)
}
/// Provide deterministic ordering of nodes such that, if any two nodes have a dominator
/// relationship, the dominator will always precede the dominated. (The relative ordering
/// of two unrelated nodes will also be consistent, but otherwise the order has no
/// meaning.) This method cannot be used to determine if either Node dominates the other.
pub fn rank_partial_cmp(&self, lhs: Node, rhs: Node) -> Option<Ordering> {
self.post_order_rank[lhs].partial_cmp(&self.post_order_rank[rhs])
}
}
pub struct Iter<'dom, Node: Idx> {
dominators: &'dom Dominators<Node>,
node: Option<Node>,
}
impl<'dom, Node: Idx> Iterator for Iter<'dom, Node> {
type Item = Node;
fn next(&mut self) -> Option<Self::Item> {
if let Some(node) = self.node {
let dom = self.dominators.immediate_dominator(node);
if dom == node {
self.node = None; // reached the root
} else {
self.node = Some(dom);
}
Some(node)
} else {
None
}
}
}