diff --git a/compiler/rustc_mir_transform/src/coverage/spans.rs b/compiler/rustc_mir_transform/src/coverage/spans.rs index b0bd514f69039..9cda71cdd0770 100644 --- a/compiler/rustc_mir_transform/src/coverage/spans.rs +++ b/compiler/rustc_mir_transform/src/coverage/spans.rs @@ -262,7 +262,7 @@ impl SpansRefiner { // a region of code, such as skipping past a hole. debug!(?prev, "prev.span starts after curr.span, so curr will be dropped"); } else { - self.some_curr = Some(CurrCovspan::new(curr.span, curr.bcb, curr.is_hole)); + self.some_curr = Some(CurrCovspan::new(curr.span, curr.bcb, false)); return true; } } diff --git a/compiler/rustc_mir_transform/src/coverage/spans/from_mir.rs b/compiler/rustc_mir_transform/src/coverage/spans/from_mir.rs index 3fa37198732ea..55cda7b442dfe 100644 --- a/compiler/rustc_mir_transform/src/coverage/spans/from_mir.rs +++ b/compiler/rustc_mir_transform/src/coverage/spans/from_mir.rs @@ -1,3 +1,6 @@ +use std::collections::VecDeque; + +use rustc_data_structures::captures::Captures; use rustc_data_structures::fx::FxHashSet; use rustc_middle::bug; use rustc_middle::mir::coverage::CoverageKind; @@ -16,8 +19,11 @@ use crate::coverage::ExtractedHirInfo; /// spans, each associated with a node in the coverage graph (BCB) and possibly /// other metadata. /// -/// The returned spans are sorted in a specific order that is expected by the -/// subsequent span-refinement step. +/// The returned spans are divided into one or more buckets, such that: +/// - The spans in each bucket are strictly after all spans in previous buckets, +/// and strictly before all spans in subsequent buckets. +/// - The contents of each bucket are also sorted, in a specific order that is +/// expected by the subsequent span-refinement step. pub(super) fn mir_to_initial_sorted_coverage_spans( mir_body: &mir::Body<'_>, hir_info: &ExtractedHirInfo, @@ -26,13 +32,21 @@ pub(super) fn mir_to_initial_sorted_coverage_spans( let &ExtractedHirInfo { body_span, .. } = hir_info; let mut initial_spans = vec![]; + let mut holes = vec![]; for (bcb, bcb_data) in basic_coverage_blocks.iter_enumerated() { - bcb_to_initial_coverage_spans(mir_body, body_span, bcb, bcb_data, &mut initial_spans); + bcb_to_initial_coverage_spans( + mir_body, + body_span, + bcb, + bcb_data, + &mut initial_spans, + &mut holes, + ); } // Only add the signature span if we found at least one span in the body. - if !initial_spans.is_empty() { + if !initial_spans.is_empty() || !holes.is_empty() { // If there is no usable signature span, add a fake one (before refinement) // to avoid an ugly gap between the body start and the first real span. // FIXME: Find a more principled way to solve this problem. @@ -44,29 +58,85 @@ pub(super) fn mir_to_initial_sorted_coverage_spans( remove_unwanted_macro_spans(&mut initial_spans); split_visible_macro_spans(&mut initial_spans); - initial_spans.sort_by(|a, b| { - // First sort by span start. - Ord::cmp(&a.span.lo(), &b.span.lo()) - // If span starts are the same, sort by span end in reverse order. - // This ensures that if spans A and B are adjacent in the list, - // and they overlap but are not equal, then either: - // - Span A extends further left, or - // - Both have the same start and span A extends further right - .then_with(|| Ord::cmp(&a.span.hi(), &b.span.hi()).reverse()) - // If two spans have the same lo & hi, put hole spans first, - // as they take precedence over non-hole spans. - .then_with(|| Ord::cmp(&a.is_hole, &b.is_hole).reverse()) + let compare_covspans = |a: &SpanFromMir, b: &SpanFromMir| { + compare_spans(a.span, b.span) // After deduplication, we want to keep only the most-dominated BCB. .then_with(|| basic_coverage_blocks.cmp_in_dominator_order(a.bcb, b.bcb).reverse()) - }); + }; + initial_spans.sort_by(compare_covspans); - // Among covspans with the same span, keep only one. Hole spans take - // precedence, otherwise keep the one with the most-dominated BCB. + // Among covspans with the same span, keep only one, + // preferring the one with the most-dominated BCB. // (Ideally we should try to preserve _all_ non-dominating BCBs, but that // requires a lot more complexity in the span refiner, for little benefit.) initial_spans.dedup_by(|b, a| a.span.source_equal(b.span)); - vec![initial_spans] + // Sort the holes, and merge overlapping/adjacent holes. + holes.sort_by(|a, b| compare_spans(a.span, b.span)); + holes.dedup_by(|b, a| a.merge_if_overlapping_or_adjacent(b)); + + // Now we're ready to start carving holes out of the initial coverage spans, + // and grouping them in buckets separated by the holes. + + let mut initial_spans = VecDeque::from(initial_spans); + let mut fragments_from_prev: Vec = vec![]; + + // For each hole: + // - Identify the spans that are entirely or partly before the hole. + // - Put those spans in a corresponding bucket, truncated to the start of the hole. + // - If one of those spans also extends after the hole, put the rest of it + // in a "fragments" vector that is processed by the next hole. + let mut buckets = (0..holes.len()).map(|_| vec![]).collect::>(); + for (hole, bucket) in holes.iter().zip(&mut buckets) { + let mut fragments_for_next = vec![]; + + // Only inspect spans that precede or overlap this hole, + // leaving the rest to be inspected by later holes. + // (This relies on the spans and holes both being sorted.) + let relevant_initial_spans = + drain_front_while(&mut initial_spans, |c| c.span.lo() < hole.span.hi()); + + for covspan in fragments_from_prev.drain(..).chain(relevant_initial_spans) { + let (before, after) = covspan.split_around_hole_span(hole.span); + bucket.extend(before); + fragments_for_next.extend(after); + } + + assert!(fragments_from_prev.is_empty()); + fragments_from_prev = fragments_for_next; + } + + // After finding the spans before each hole, any remaining fragments/spans + // form their own final bucket, after the final hole. + // (If there were no holes, this will just be all of the initial spans.) + fragments_from_prev.extend(initial_spans); + buckets.push(fragments_from_prev); + + // Make sure each individual bucket is still internally sorted. + for bucket in &mut buckets { + bucket.sort_by(compare_covspans); + } + buckets +} + +fn compare_spans(a: Span, b: Span) -> std::cmp::Ordering { + // First sort by span start. + Ord::cmp(&a.lo(), &b.lo()) + // If span starts are the same, sort by span end in reverse order. + // This ensures that if spans A and B are adjacent in the list, + // and they overlap but are not equal, then either: + // - Span A extends further left, or + // - Both have the same start and span A extends further right + .then_with(|| Ord::cmp(&a.hi(), &b.hi()).reverse()) +} + +/// Similar to `.drain(..)`, but stops just before it would remove an item not +/// satisfying the predicate. +fn drain_front_while<'a, T>( + queue: &'a mut VecDeque, + mut pred_fn: impl FnMut(&T) -> bool, +) -> impl Iterator + Captures<'a> { + std::iter::from_fn(move || if pred_fn(queue.front()?) { queue.pop_front() } else { None }) } /// Macros that expand into branches (e.g. `assert!`, `trace!`) tend to generate @@ -79,8 +149,8 @@ pub(super) fn mir_to_initial_sorted_coverage_spans( fn remove_unwanted_macro_spans(initial_spans: &mut Vec) { let mut seen_macro_spans = FxHashSet::default(); initial_spans.retain(|covspan| { - // Ignore (retain) hole spans and non-macro-expansion spans. - if covspan.is_hole || covspan.visible_macro.is_none() { + // Ignore (retain) non-macro-expansion spans. + if covspan.visible_macro.is_none() { return true; } @@ -97,10 +167,6 @@ fn split_visible_macro_spans(initial_spans: &mut Vec) { let mut extra_spans = vec![]; initial_spans.retain(|covspan| { - if covspan.is_hole { - return true; - } - let Some(visible_macro) = covspan.visible_macro else { return true }; let split_len = visible_macro.as_str().len() as u32 + 1; @@ -113,9 +179,8 @@ fn split_visible_macro_spans(initial_spans: &mut Vec) { return true; } - assert!(!covspan.is_hole); - extra_spans.push(SpanFromMir::new(before, covspan.visible_macro, covspan.bcb, false)); - extra_spans.push(SpanFromMir::new(after, covspan.visible_macro, covspan.bcb, false)); + extra_spans.push(SpanFromMir::new(before, covspan.visible_macro, covspan.bcb)); + extra_spans.push(SpanFromMir::new(after, covspan.visible_macro, covspan.bcb)); false // Discard the original covspan that we just split. }); @@ -135,6 +200,7 @@ fn bcb_to_initial_coverage_spans<'a, 'tcx>( bcb: BasicCoverageBlock, bcb_data: &'a BasicCoverageBlockData, initial_covspans: &mut Vec, + holes: &mut Vec, ) { for &bb in &bcb_data.basic_blocks { let data = &mir_body[bb]; @@ -146,26 +212,31 @@ fn bcb_to_initial_coverage_spans<'a, 'tcx>( .filter(|(span, _)| !span.source_equal(body_span)) }; + let mut extract_statement_span = |statement| { + let expn_span = filtered_statement_span(statement)?; + let (span, visible_macro) = unexpand(expn_span)?; + + // A statement that looks like the assignment of a closure expression + // is treated as a "hole" span, to be carved out of other spans. + if is_closure_like(statement) { + holes.push(Hole { span }); + } else { + initial_covspans.push(SpanFromMir::new(span, visible_macro, bcb)); + } + Some(()) + }; for statement in data.statements.iter() { - let _: Option<()> = try { - let expn_span = filtered_statement_span(statement)?; - let (span, visible_macro) = unexpand(expn_span)?; - - // A statement that looks like the assignment of a closure expression - // is treated as a "hole" span, to be carved out of other spans. - let covspan = - SpanFromMir::new(span, visible_macro, bcb, is_closure_like(statement)); - initial_covspans.push(covspan); - }; + extract_statement_span(statement); } - let _: Option<()> = try { - let terminator = data.terminator(); + let mut extract_terminator_span = |terminator| { let expn_span = filtered_terminator_span(terminator)?; let (span, visible_macro) = unexpand(expn_span)?; - initial_covspans.push(SpanFromMir::new(span, visible_macro, bcb, false)); + initial_covspans.push(SpanFromMir::new(span, visible_macro, bcb)); + Some(()) }; + extract_terminator_span(data.terminator()); } } @@ -333,6 +404,22 @@ fn unexpand_into_body_span_with_prev( Some((curr, prev)) } +#[derive(Debug)] +struct Hole { + span: Span, +} + +impl Hole { + fn merge_if_overlapping_or_adjacent(&mut self, other: &mut Self) -> bool { + if !self.span.overlaps_or_adjacent(other.span) { + return false; + } + + self.span = self.span.to(other.span); + true + } +} + #[derive(Debug)] pub(super) struct SpanFromMir { /// A span that has been extracted from MIR and then "un-expanded" back to @@ -345,23 +432,30 @@ pub(super) struct SpanFromMir { pub(super) span: Span, visible_macro: Option, pub(super) bcb: BasicCoverageBlock, - /// If true, this covspan represents a "hole" that should be carved out - /// from other spans, e.g. because it represents a closure expression that - /// will be instrumented separately as its own function. - pub(super) is_hole: bool, } impl SpanFromMir { fn for_fn_sig(fn_sig_span: Span) -> Self { - Self::new(fn_sig_span, None, START_BCB, false) + Self::new(fn_sig_span, None, START_BCB) + } + + fn new(span: Span, visible_macro: Option, bcb: BasicCoverageBlock) -> Self { + Self { span, visible_macro, bcb } } - fn new( - span: Span, - visible_macro: Option, - bcb: BasicCoverageBlock, - is_hole: bool, - ) -> Self { - Self { span, visible_macro, bcb, is_hole } + /// Splits this span into 0-2 parts: + /// - The part that is strictly before the hole span, if any. + /// - The part that is strictly after the hole span, if any. + fn split_around_hole_span(&self, hole_span: Span) -> (Option, Option) { + let before = try { + let span = self.span.trim_end(hole_span)?; + Self { span, ..*self } + }; + let after = try { + let span = self.span.trim_start(hole_span)?; + Self { span, ..*self } + }; + + (before, after) } } diff --git a/tests/coverage/closure_macro.cov-map b/tests/coverage/closure_macro.cov-map index fd8fbd9fa7575..156947f4e21c1 100644 --- a/tests/coverage/closure_macro.cov-map +++ b/tests/coverage/closure_macro.cov-map @@ -7,16 +7,14 @@ Number of file 0 mappings: 1 - Code(Counter(0)) at (prev + 29, 1) to (start + 2, 2) Function name: closure_macro::main -Raw bytes (36): 0x[01, 01, 01, 01, 05, 06, 01, 21, 01, 01, 21, 02, 02, 09, 00, 12, 02, 00, 0f, 00, 54, 05, 00, 54, 00, 55, 02, 02, 09, 02, 0b, 01, 03, 01, 00, 02] +Raw bytes (31): 0x[01, 01, 01, 01, 05, 05, 01, 21, 01, 01, 21, 02, 02, 09, 00, 0f, 05, 00, 54, 00, 55, 02, 02, 09, 02, 0b, 01, 03, 01, 00, 02] Number of files: 1 - file 0 => global file 1 Number of expressions: 1 - expression 0 operands: lhs = Counter(0), rhs = Counter(1) -Number of file 0 mappings: 6 +Number of file 0 mappings: 5 - Code(Counter(0)) at (prev + 33, 1) to (start + 1, 33) -- Code(Expression(0, Sub)) at (prev + 2, 9) to (start + 0, 18) - = (c0 - c1) -- Code(Expression(0, Sub)) at (prev + 0, 15) to (start + 0, 84) +- Code(Expression(0, Sub)) at (prev + 2, 9) to (start + 0, 15) = (c0 - c1) - Code(Counter(1)) at (prev + 0, 84) to (start + 0, 85) - Code(Expression(0, Sub)) at (prev + 2, 9) to (start + 2, 11) diff --git a/tests/coverage/closure_macro_async.cov-map b/tests/coverage/closure_macro_async.cov-map index 43b52008f33e3..0f2b4e0174836 100644 --- a/tests/coverage/closure_macro_async.cov-map +++ b/tests/coverage/closure_macro_async.cov-map @@ -15,16 +15,14 @@ Number of file 0 mappings: 1 - Code(Counter(0)) at (prev + 35, 1) to (start + 0, 43) Function name: closure_macro_async::test::{closure#0} -Raw bytes (36): 0x[01, 01, 01, 01, 05, 06, 01, 23, 2b, 01, 21, 02, 02, 09, 00, 12, 02, 00, 0f, 00, 54, 05, 00, 54, 00, 55, 02, 02, 09, 02, 0b, 01, 03, 01, 00, 02] +Raw bytes (31): 0x[01, 01, 01, 01, 05, 05, 01, 23, 2b, 01, 21, 02, 02, 09, 00, 0f, 05, 00, 54, 00, 55, 02, 02, 09, 02, 0b, 01, 03, 01, 00, 02] Number of files: 1 - file 0 => global file 1 Number of expressions: 1 - expression 0 operands: lhs = Counter(0), rhs = Counter(1) -Number of file 0 mappings: 6 +Number of file 0 mappings: 5 - Code(Counter(0)) at (prev + 35, 43) to (start + 1, 33) -- Code(Expression(0, Sub)) at (prev + 2, 9) to (start + 0, 18) - = (c0 - c1) -- Code(Expression(0, Sub)) at (prev + 0, 15) to (start + 0, 84) +- Code(Expression(0, Sub)) at (prev + 2, 9) to (start + 0, 15) = (c0 - c1) - Code(Counter(1)) at (prev + 0, 84) to (start + 0, 85) - Code(Expression(0, Sub)) at (prev + 2, 9) to (start + 2, 11)