//! A number of passes which remove various redundancies in the CFG. //! //! The `SimplifyCfg` pass gets rid of unnecessary blocks in the CFG, whereas the `SimplifyLocals` //! gets rid of all the unnecessary local variable declarations. //! //! The `SimplifyLocals` pass is kinda expensive and therefore not very suitable to be run often. //! Most of the passes should not care or be impacted in meaningful ways due to extra locals //! either, so running the pass once, right before codegen, should suffice. //! //! On the other side of the spectrum, the `SimplifyCfg` pass is considerably cheap to run, thus //! one should run it after every pass which may modify CFG in significant ways. This pass must //! also be run before any analysis passes because it removes dead blocks, and some of these can be //! ill-typed. //! //! The cause of this typing issue is typeck allowing most blocks whose end is not reachable have //! an arbitrary return type, rather than having the usual () return type (as a note, typeck's //! notion of reachability is in fact slightly weaker than MIR CFG reachability - see #31617). A //! standard example of the situation is: //! //! ```rust //! fn example() { //! let _a: char = { return; }; //! } //! ``` //! //! Here the block (`{ return; }`) has the return type `char`, rather than `()`, but the MIR we //! naively generate still contains the `_a = ()` write in the unreachable block "after" the //! return. use crate::MirPass; use rustc_data_structures::stable_set::FxHashSet; use rustc_index::vec::{Idx, IndexVec}; use rustc_middle::mir::coverage::*; use rustc_middle::mir::visit::{MutVisitor, MutatingUseContext, PlaceContext, Visitor}; use rustc_middle::mir::*; use rustc_middle::ty::TyCtxt; use smallvec::SmallVec; use std::borrow::Cow; use std::convert::TryInto; pub struct SimplifyCfg { label: String, } impl SimplifyCfg { pub fn new(label: &str) -> Self { SimplifyCfg { label: format!("SimplifyCfg-{}", label) } } } pub fn simplify_cfg<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) { CfgSimplifier::new(body).simplify(); remove_dead_blocks(tcx, body); // FIXME: Should probably be moved into some kind of pass manager body.basic_blocks_mut().raw.shrink_to_fit(); } impl<'tcx> MirPass<'tcx> for SimplifyCfg { fn name(&self) -> Cow<'_, str> { Cow::Borrowed(&self.label) } fn run_pass(&self, tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) { debug!("SimplifyCfg({:?}) - simplifying {:?}", self.label, body.source); simplify_cfg(tcx, body); } } pub struct CfgSimplifier<'a, 'tcx> { basic_blocks: &'a mut IndexVec>, pred_count: IndexVec, } impl<'a, 'tcx> CfgSimplifier<'a, 'tcx> { pub fn new(body: &'a mut Body<'tcx>) -> Self { let mut pred_count = IndexVec::from_elem(0u32, body.basic_blocks()); // we can't use mir.predecessors() here because that counts // dead blocks, which we don't want to. pred_count[START_BLOCK] = 1; for (_, data) in traversal::preorder(body) { if let Some(ref term) = data.terminator { for tgt in term.successors() { pred_count[tgt] += 1; } } } let basic_blocks = body.basic_blocks_mut(); CfgSimplifier { basic_blocks, pred_count } } pub fn simplify(mut self) { self.strip_nops(); // Vec of the blocks that should be merged. We store the indices here, instead of the // statements itself to avoid moving the (relatively) large statements twice. // We do not push the statements directly into the target block (`bb`) as that is slower // due to additional reallocations let mut merged_blocks = Vec::new(); loop { let mut changed = false; for bb in self.basic_blocks.indices() { if self.pred_count[bb] == 0 { continue; } debug!("simplifying {:?}", bb); let mut terminator = self.basic_blocks[bb].terminator.take().expect("invalid terminator state"); for successor in terminator.successors_mut() { self.collapse_goto_chain(successor, &mut changed); } let mut inner_changed = true; merged_blocks.clear(); while inner_changed { inner_changed = false; inner_changed |= self.simplify_branch(&mut terminator); inner_changed |= self.merge_successor(&mut merged_blocks, &mut terminator); changed |= inner_changed; } let statements_to_merge = merged_blocks.iter().map(|&i| self.basic_blocks[i].statements.len()).sum(); if statements_to_merge > 0 { let mut statements = std::mem::take(&mut self.basic_blocks[bb].statements); statements.reserve(statements_to_merge); for &from in &merged_blocks { statements.append(&mut self.basic_blocks[from].statements); } self.basic_blocks[bb].statements = statements; } self.basic_blocks[bb].terminator = Some(terminator); } if !changed { break; } } } /// This function will return `None` if /// * the block has statements /// * the block has a terminator other than `goto` /// * the block has no terminator (meaning some other part of the current optimization stole it) fn take_terminator_if_simple_goto(&mut self, bb: BasicBlock) -> Option> { match self.basic_blocks[bb] { BasicBlockData { ref statements, terminator: ref mut terminator @ Some(Terminator { kind: TerminatorKind::Goto { .. }, .. }), .. } if statements.is_empty() => terminator.take(), // if `terminator` is None, this means we are in a loop. In that // case, let all the loop collapse to its entry. _ => None, } } /// Collapse a goto chain starting from `start` fn collapse_goto_chain(&mut self, start: &mut BasicBlock, changed: &mut bool) { // Using `SmallVec` here, because in some logs on libcore oli-obk saw many single-element // goto chains. We should probably benchmark different sizes. let mut terminators: SmallVec<[_; 1]> = Default::default(); let mut current = *start; while let Some(terminator) = self.take_terminator_if_simple_goto(current) { let Terminator { kind: TerminatorKind::Goto { target }, .. } = terminator else { unreachable!(); }; terminators.push((current, terminator)); current = target; } let last = current; *start = last; while let Some((current, mut terminator)) = terminators.pop() { let Terminator { kind: TerminatorKind::Goto { ref mut target }, .. } = terminator else { unreachable!(); }; *changed |= *target != last; *target = last; debug!("collapsing goto chain from {:?} to {:?}", current, target); if self.pred_count[current] == 1 { // This is the last reference to current, so the pred-count to // to target is moved into the current block. self.pred_count[current] = 0; } else { self.pred_count[*target] += 1; self.pred_count[current] -= 1; } self.basic_blocks[current].terminator = Some(terminator); } } // merge a block with 1 `goto` predecessor to its parent fn merge_successor( &mut self, merged_blocks: &mut Vec, terminator: &mut Terminator<'tcx>, ) -> bool { let target = match terminator.kind { TerminatorKind::Goto { target } if self.pred_count[target] == 1 => target, _ => return false, }; debug!("merging block {:?} into {:?}", target, terminator); *terminator = match self.basic_blocks[target].terminator.take() { Some(terminator) => terminator, None => { // unreachable loop - this should not be possible, as we // don't strand blocks, but handle it correctly. return false; } }; merged_blocks.push(target); self.pred_count[target] = 0; true } // turn a branch with all successors identical to a goto fn simplify_branch(&mut self, terminator: &mut Terminator<'tcx>) -> bool { match terminator.kind { TerminatorKind::SwitchInt { .. } => {} _ => return false, }; let first_succ = { if let Some(first_succ) = terminator.successors().next() { if terminator.successors().all(|s| s == first_succ) { let count = terminator.successors().count(); self.pred_count[first_succ] -= (count - 1) as u32; first_succ } else { return false; } } else { return false; } }; debug!("simplifying branch {:?}", terminator); terminator.kind = TerminatorKind::Goto { target: first_succ }; true } fn strip_nops(&mut self) { for blk in self.basic_blocks.iter_mut() { blk.statements.retain(|stmt| !matches!(stmt.kind, StatementKind::Nop)) } } } pub fn remove_dead_blocks<'tcx>(tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) { let reachable = traversal::reachable_as_bitset(body); let num_blocks = body.basic_blocks().len(); if num_blocks == reachable.count() { return; } let basic_blocks = body.basic_blocks.as_mut(); let source_scopes = &body.source_scopes; let mut replacements: Vec<_> = (0..num_blocks).map(BasicBlock::new).collect(); let mut used_blocks = 0; for alive_index in reachable.iter() { let alive_index = alive_index.index(); replacements[alive_index] = BasicBlock::new(used_blocks); if alive_index != used_blocks { // Swap the next alive block data with the current available slot. Since // alive_index is non-decreasing this is a valid operation. basic_blocks.raw.swap(alive_index, used_blocks); } used_blocks += 1; } if tcx.sess.instrument_coverage() { save_unreachable_coverage(basic_blocks, source_scopes, used_blocks); } basic_blocks.raw.truncate(used_blocks); for block in basic_blocks { for target in block.terminator_mut().successors_mut() { *target = replacements[target.index()]; } } } /// Some MIR transforms can determine at compile time that a sequences of /// statements will never be executed, so they can be dropped from the MIR. /// For example, an `if` or `else` block that is guaranteed to never be executed /// because its condition can be evaluated at compile time, such as by const /// evaluation: `if false { ... }`. /// /// Those statements are bypassed by redirecting paths in the CFG around the /// `dead blocks`; but with `-C instrument-coverage`, the dead blocks usually /// include `Coverage` statements representing the Rust source code regions to /// be counted at runtime. Without these `Coverage` statements, the regions are /// lost, and the Rust source code will show no coverage information. /// /// What we want to show in a coverage report is the dead code with coverage /// counts of `0`. To do this, we need to save the code regions, by injecting /// `Unreachable` coverage statements. These are non-executable statements whose /// code regions are still recorded in the coverage map, representing regions /// with `0` executions. /// /// If there are no live `Counter` `Coverage` statements remaining, we remove /// dead `Coverage` statements along with the dead blocks. Since at least one /// counter per function is required by LLVM (and necessary, to add the /// `function_hash` to the counter's call to the LLVM intrinsic /// `instrprof.increment()`). /// /// The `generator::StateTransform` MIR pass and MIR inlining can create /// atypical conditions, where all live `Counter`s are dropped from the MIR. /// /// With MIR inlining we can have coverage counters belonging to different /// instances in a single body, so the strategy described above is applied to /// coverage counters from each instance individually. fn save_unreachable_coverage( basic_blocks: &mut IndexVec>, source_scopes: &IndexVec>, first_dead_block: usize, ) { // Identify instances that still have some live coverage counters left. let mut live = FxHashSet::default(); for basic_block in &basic_blocks.raw[0..first_dead_block] { for statement in &basic_block.statements { let StatementKind::Coverage(coverage) = &statement.kind else { continue }; let CoverageKind::Counter { .. } = coverage.kind else { continue }; let instance = statement.source_info.scope.inlined_instance(source_scopes); live.insert(instance); } } if live.is_empty() { return; } // Retain coverage for instances that still have some live counters left. let mut retained_coverage = Vec::new(); for dead_block in &basic_blocks.raw[first_dead_block..] { for statement in &dead_block.statements { let StatementKind::Coverage(coverage) = &statement.kind else { continue }; let Some(code_region) = &coverage.code_region else { continue }; let instance = statement.source_info.scope.inlined_instance(source_scopes); if live.contains(&instance) { retained_coverage.push((statement.source_info, code_region.clone())); } } } let start_block = &mut basic_blocks[START_BLOCK]; start_block.statements.extend(retained_coverage.into_iter().map( |(source_info, code_region)| Statement { source_info, kind: StatementKind::Coverage(Box::new(Coverage { kind: CoverageKind::Unreachable, code_region: Some(code_region), })), }, )); } pub struct SimplifyLocals; impl<'tcx> MirPass<'tcx> for SimplifyLocals { fn is_enabled(&self, sess: &rustc_session::Session) -> bool { sess.mir_opt_level() > 0 } fn run_pass(&self, tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) { trace!("running SimplifyLocals on {:?}", body.source); simplify_locals(body, tcx); } } pub fn simplify_locals<'tcx>(body: &mut Body<'tcx>, tcx: TyCtxt<'tcx>) { // First, we're going to get a count of *actual* uses for every `Local`. let mut used_locals = UsedLocals::new(body); // Next, we're going to remove any `Local` with zero actual uses. When we remove those // `Locals`, we're also going to subtract any uses of other `Locals` from the `used_locals` // count. For example, if we removed `_2 = discriminant(_1)`, then we'll subtract one from // `use_counts[_1]`. That in turn might make `_1` unused, so we loop until we hit a // fixedpoint where there are no more unused locals. remove_unused_definitions(&mut used_locals, body); // Finally, we'll actually do the work of shrinking `body.local_decls` and remapping the `Local`s. let map = make_local_map(&mut body.local_decls, &used_locals); // Only bother running the `LocalUpdater` if we actually found locals to remove. if map.iter().any(Option::is_none) { // Update references to all vars and tmps now let mut updater = LocalUpdater { map, tcx }; updater.visit_body(body); body.local_decls.shrink_to_fit(); } } /// Construct the mapping while swapping out unused stuff out from the `vec`. fn make_local_map( local_decls: &mut IndexVec, used_locals: &UsedLocals, ) -> IndexVec> { let mut map: IndexVec> = IndexVec::from_elem(None, &*local_decls); let mut used = Local::new(0); for alive_index in local_decls.indices() { // `is_used` treats the `RETURN_PLACE` and arguments as used. if !used_locals.is_used(alive_index) { continue; } map[alive_index] = Some(used); if alive_index != used { local_decls.swap(alive_index, used); } used.increment_by(1); } local_decls.truncate(used.index()); map } /// Keeps track of used & unused locals. struct UsedLocals { increment: bool, arg_count: u32, use_count: IndexVec, } impl UsedLocals { /// Determines which locals are used & unused in the given body. fn new(body: &Body<'_>) -> Self { let mut this = Self { increment: true, arg_count: body.arg_count.try_into().unwrap(), use_count: IndexVec::from_elem(0, &body.local_decls), }; this.visit_body(body); this } /// Checks if local is used. /// /// Return place and arguments are always considered used. fn is_used(&self, local: Local) -> bool { trace!("is_used({:?}): use_count: {:?}", local, self.use_count[local]); local.as_u32() <= self.arg_count || self.use_count[local] != 0 } /// Updates the use counts to reflect the removal of given statement. fn statement_removed(&mut self, statement: &Statement<'_>) { self.increment = false; // The location of the statement is irrelevant. let location = Location { block: START_BLOCK, statement_index: 0 }; self.visit_statement(statement, location); } /// Visits a left-hand side of an assignment. fn visit_lhs(&mut self, place: &Place<'_>, location: Location) { if place.is_indirect() { // A use, not a definition. self.visit_place(place, PlaceContext::MutatingUse(MutatingUseContext::Store), location); } else { // A definition. The base local itself is not visited, so this occurrence is not counted // toward its use count. There might be other locals still, used in an indexing // projection. self.super_projection( place.as_ref(), PlaceContext::MutatingUse(MutatingUseContext::Projection), location, ); } } } impl<'tcx> Visitor<'tcx> for UsedLocals { fn visit_statement(&mut self, statement: &Statement<'tcx>, location: Location) { match statement.kind { StatementKind::CopyNonOverlapping(..) | StatementKind::Retag(..) | StatementKind::Coverage(..) | StatementKind::FakeRead(..) | StatementKind::AscribeUserType(..) => { self.super_statement(statement, location); } StatementKind::Nop => {} StatementKind::StorageLive(_local) | StatementKind::StorageDead(_local) => {} StatementKind::Assign(box (ref place, ref rvalue)) => { if rvalue.is_safe_to_remove() { self.visit_lhs(place, location); self.visit_rvalue(rvalue, location); } else { self.super_statement(statement, location); } } StatementKind::SetDiscriminant { ref place, variant_index: _ } | StatementKind::Deinit(ref place) => { self.visit_lhs(place, location); } } } fn visit_local(&mut self, local: Local, _ctx: PlaceContext, _location: Location) { if self.increment { self.use_count[local] += 1; } else { assert_ne!(self.use_count[local], 0); self.use_count[local] -= 1; } } } /// Removes unused definitions. Updates the used locals to reflect the changes made. fn remove_unused_definitions(used_locals: &mut UsedLocals, body: &mut Body<'_>) { // The use counts are updated as we remove the statements. A local might become unused // during the retain operation, leading to a temporary inconsistency (storage statements or // definitions referencing the local might remain). For correctness it is crucial that this // computation reaches a fixed point. let mut modified = true; while modified { modified = false; for data in body.basic_blocks_mut() { // Remove unnecessary StorageLive and StorageDead annotations. data.statements.retain(|statement| { let keep = match &statement.kind { StatementKind::StorageLive(local) | StatementKind::StorageDead(local) => { used_locals.is_used(*local) } StatementKind::Assign(box (place, _)) => used_locals.is_used(place.local), StatementKind::SetDiscriminant { ref place, .. } | StatementKind::Deinit(ref place) => used_locals.is_used(place.local), _ => true, }; if !keep { trace!("removing statement {:?}", statement); modified = true; used_locals.statement_removed(statement); } keep }); } } } struct LocalUpdater<'tcx> { map: IndexVec>, tcx: TyCtxt<'tcx>, } impl<'tcx> MutVisitor<'tcx> for LocalUpdater<'tcx> { fn tcx(&self) -> TyCtxt<'tcx> { self.tcx } fn visit_local(&mut self, l: &mut Local, _: PlaceContext, _: Location) { *l = self.map[*l].unwrap(); } }