compiler/rustc_mir/src/transform/coverage/query.rs - third_party/github.com/rust-lang/rust - Git at Google

 use super::*;

 use rustc_middle::mir::coverage::*;
 use rustc_middle::mir::visit::Visitor;
 use rustc_middle::mir::{self, Coverage, CoverageInfo, Location};
 use rustc_middle::ty::query::Providers;
 use rustc_middle::ty::TyCtxt;
 use rustc_span::def_id::DefId;

 /// The `query` provider for `CoverageInfo`, requested by `codegen_coverage()` (to inject each
 /// counter) and `FunctionCoverage::new()` (to extract the coverage map metadata from the MIR).
 pub(crate) fn provide(providers: &mut Providers) {
     providers.coverageinfo = |tcx, def_id| coverageinfo_from_mir(tcx, def_id);
     providers.covered_file_name = |tcx, def_id| covered_file_name(tcx, def_id);
     providers.covered_code_regions = |tcx, def_id| covered_code_regions(tcx, def_id);
 }

 /// The `num_counters` argument to `llvm.instrprof.increment` is the max counter_id + 1, or in
 /// other words, the number of counter value references injected into the MIR (plus 1 for the
 /// reserved `ZERO` counter, which uses counter ID `0` when included in an expression). Injected
 /// counters have a counter ID from `1..num_counters-1`.
 ///
 /// `num_expressions` is the number of counter expressions added to the MIR body.
 ///
 /// Both `num_counters` and `num_expressions` are used to initialize new vectors, during backend
 /// code generate, to lookup counters and expressions by simple u32 indexes.
 ///
 /// MIR optimization may split and duplicate some BasicBlock sequences, or optimize out some code
 /// including injected counters. (It is OK if some counters are optimized out, but those counters
 /// are still included in the total `num_counters` or `num_expressions`.) Simply counting the
 /// calls may not work; but computing the number of counters or expressions by adding `1` to the
 /// highest ID (for a given instrumented function) is valid.
 ///
 /// This visitor runs twice, first with `add_missing_operands` set to `false`, to find the maximum
 /// counter ID and maximum expression ID based on their enum variant `id` fields; then, as a
 /// safeguard, with `add_missing_operands` set to `true`, to find any other counter or expression
 /// IDs referenced by expression operands, if not already seen.
 ///
 /// Ideally, each operand ID in a MIR `CoverageKind::Expression` will have a separate MIR `Coverage`
 /// statement for the `Counter` or `Expression` with the referenced ID. but since current or future
 /// MIR optimizations can theoretically optimize out segments of a MIR, it may not be possible to
 /// guarantee this, so the second pass ensures the `CoverageInfo` counts include all referenced IDs.
 struct CoverageVisitor {
     info: CoverageInfo,
     add_missing_operands: bool,
 }

 impl CoverageVisitor {
     /// Updates `num_counters` to the maximum encountered zero-based counter_id plus 1. Note the
     /// final computed number of counters should be the number of all `CoverageKind::Counter`
     /// statements in the MIR *plus one* for the implicit `ZERO` counter.
     #[inline(always)]
     fn update_num_counters(&mut self, counter_id: u32) {
         self.info.num_counters = std::cmp::max(self.info.num_counters, counter_id + 1);
     }

     /// Computes an expression index for each expression ID, and updates `num_expressions` to the
     /// maximum encountered index plus 1.
     #[inline(always)]
     fn update_num_expressions(&mut self, expression_id: u32) {
         let expression_index = u32::MAX - expression_id;
         self.info.num_expressions = std::cmp::max(self.info.num_expressions, expression_index + 1);
     }

     fn update_from_expression_operand(&mut self, operand_id: u32) {
         if operand_id >= self.info.num_counters {
             let operand_as_expression_index = u32::MAX - operand_id;
             if operand_as_expression_index >= self.info.num_expressions {
                 // The operand ID is outside the known range of counter IDs and also outside the
                 // known range of expression IDs. In either case, the result of a missing operand
                 // (if and when used in an expression) will be zero, so from a computation
                 // perspective, it doesn't matter whether it is interepretted as a counter or an
                 // expression.
                 //
                 // However, the `num_counters` and `num_expressions` query results are used to
                 // allocate arrays when generating the coverage map (during codegen), so choose
                 // the type that grows either `num_counters` or `num_expressions` the least.
                 if operand_id - self.info.num_counters
                     < operand_as_expression_index - self.info.num_expressions
                 {
                     self.update_num_counters(operand_id)
                 } else {
                     self.update_num_expressions(operand_id)
                 }
             }
         }
     }
 }

 impl Visitor<'_> for CoverageVisitor {
     fn visit_coverage(&mut self, coverage: &Coverage, _location: Location) {
         if self.add_missing_operands {
             match coverage.kind {
                 CoverageKind::Expression { lhs, rhs, .. } => {
                     self.update_from_expression_operand(u32::from(lhs));
                     self.update_from_expression_operand(u32::from(rhs));
                 }
                 _ => {}
             }
         } else {
             match coverage.kind {
                 CoverageKind::Counter { id, .. } => {
                     self.update_num_counters(u32::from(id));
                 }
                 CoverageKind::Expression { id, .. } => {
                     self.update_num_expressions(u32::from(id));
                 }
                 _ => {}
             }
         }
     }
 }

 fn coverageinfo_from_mir<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId) -> CoverageInfo {
     let mir_body = tcx.optimized_mir(def_id);

     let mut coverage_visitor = CoverageVisitor {
         // num_counters always has at least the `ZERO` counter.
         info: CoverageInfo { num_counters: 1, num_expressions: 0 },
         add_missing_operands: false,
     };

     coverage_visitor.visit_body(mir_body);

     coverage_visitor.add_missing_operands = true;
     coverage_visitor.visit_body(mir_body);

     coverage_visitor.info
 }

 fn covered_file_name<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId) -> Option<Symbol> {
     let mir_body = tcx.optimized_mir(def_id);
     for bb_data in mir_body.basic_blocks().iter() {
         for statement in bb_data.statements.iter() {
             if let StatementKind::Coverage(box ref coverage) = statement.kind {
                 if let Some(code_region) = coverage.code_region.as_ref() {
                     return Some(code_region.file_name);
                 }
             }
         }
     }
     None
 }

 fn covered_code_regions<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId) -> Vec<&'tcx CodeRegion> {
     let mir_body: &'tcx mir::Body<'tcx> = tcx.optimized_mir(def_id);
     mir_body
         .basic_blocks()
         .iter()
         .map(|data| {
             data.statements.iter().filter_map(|statement| match statement.kind {
                 StatementKind::Coverage(box ref coverage) => {
                     coverage.code_region.as_ref() // may be None
                 }
                 _ => None,
             })
         })
         .flatten()
         .collect()
 }
	use super::*;

	use rustc_middle::mir::coverage::*;
	use rustc_middle::mir::visit::Visitor;
	use rustc_middle::mir::{self, Coverage, CoverageInfo, Location};
	use rustc_middle::ty::query::Providers;
	use rustc_middle::ty::TyCtxt;
	use rustc_span::def_id::DefId;

	/// The `query` provider for `CoverageInfo`, requested by `codegen_coverage()` (to inject each
	/// counter) and `FunctionCoverage::new()` (to extract the coverage map metadata from the MIR).
	pub(crate) fn provide(providers: &mut Providers) {
	providers.coverageinfo = \|tcx, def_id\| coverageinfo_from_mir(tcx, def_id);
	providers.covered_file_name = \|tcx, def_id\| covered_file_name(tcx, def_id);
	providers.covered_code_regions = \|tcx, def_id\| covered_code_regions(tcx, def_id);
	}

	/// The `num_counters` argument to `llvm.instrprof.increment` is the max counter_id + 1, or in
	/// other words, the number of counter value references injected into the MIR (plus 1 for the
	/// reserved `ZERO` counter, which uses counter ID `0` when included in an expression). Injected
	/// counters have a counter ID from `1..num_counters-1`.
	///
	/// `num_expressions` is the number of counter expressions added to the MIR body.
	///
	/// Both `num_counters` and `num_expressions` are used to initialize new vectors, during backend
	/// code generate, to lookup counters and expressions by simple u32 indexes.
	///
	/// MIR optimization may split and duplicate some BasicBlock sequences, or optimize out some code
	/// including injected counters. (It is OK if some counters are optimized out, but those counters
	/// are still included in the total `num_counters` or `num_expressions`.) Simply counting the
	/// calls may not work; but computing the number of counters or expressions by adding `1` to the
	/// highest ID (for a given instrumented function) is valid.
	///
	/// This visitor runs twice, first with `add_missing_operands` set to `false`, to find the maximum
	/// counter ID and maximum expression ID based on their enum variant `id` fields; then, as a
	/// safeguard, with `add_missing_operands` set to `true`, to find any other counter or expression
	/// IDs referenced by expression operands, if not already seen.
	///
	/// Ideally, each operand ID in a MIR `CoverageKind::Expression` will have a separate MIR `Coverage`
	/// statement for the `Counter` or `Expression` with the referenced ID. but since current or future
	/// MIR optimizations can theoretically optimize out segments of a MIR, it may not be possible to
	/// guarantee this, so the second pass ensures the `CoverageInfo` counts include all referenced IDs.
	struct CoverageVisitor {
	info: CoverageInfo,
	add_missing_operands: bool,
	}

	impl CoverageVisitor {
	/// Updates `num_counters` to the maximum encountered zero-based counter_id plus 1. Note the
	/// final computed number of counters should be the number of all `CoverageKind::Counter`
	/// statements in the MIR plus one for the implicit `ZERO` counter.
	#[inline(always)]
	fn update_num_counters(&mut self, counter_id: u32) {
	self.info.num_counters = std::cmp::max(self.info.num_counters, counter_id + 1);
	}

	/// Computes an expression index for each expression ID, and updates `num_expressions` to the
	/// maximum encountered index plus 1.
	#[inline(always)]
	fn update_num_expressions(&mut self, expression_id: u32) {
	let expression_index = u32::MAX - expression_id;
	self.info.num_expressions = std::cmp::max(self.info.num_expressions, expression_index + 1);
	}

	fn update_from_expression_operand(&mut self, operand_id: u32) {
	if operand_id >= self.info.num_counters {
	let operand_as_expression_index = u32::MAX - operand_id;
	if operand_as_expression_index >= self.info.num_expressions {
	// The operand ID is outside the known range of counter IDs and also outside the
	// known range of expression IDs. In either case, the result of a missing operand
	// (if and when used in an expression) will be zero, so from a computation
	// perspective, it doesn't matter whether it is interepretted as a counter or an
	// expression.
	//
	// However, the `num_counters` and `num_expressions` query results are used to
	// allocate arrays when generating the coverage map (during codegen), so choose
	// the type that grows either `num_counters` or `num_expressions` the least.
	if operand_id - self.info.num_counters
	< operand_as_expression_index - self.info.num_expressions
	{
	self.update_num_counters(operand_id)
	} else {
	self.update_num_expressions(operand_id)
	}
	}
	}
	}
	}

	impl Visitor<'_> for CoverageVisitor {
	fn visit_coverage(&mut self, coverage: &Coverage, _location: Location) {
	if self.add_missing_operands {
	match coverage.kind {
	CoverageKind::Expression { lhs, rhs, .. } => {
	self.update_from_expression_operand(u32::from(lhs));
	self.update_from_expression_operand(u32::from(rhs));
	}
	_ => {}
	}
	} else {
	match coverage.kind {
	CoverageKind::Counter { id, .. } => {
	self.update_num_counters(u32::from(id));
	}
	CoverageKind::Expression { id, .. } => {
	self.update_num_expressions(u32::from(id));
	}
	_ => {}
	}
	}
	}
	}

	fn coverageinfo_from_mir<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId) -> CoverageInfo {
	let mir_body = tcx.optimized_mir(def_id);

	let mut coverage_visitor = CoverageVisitor {
	// num_counters always has at least the `ZERO` counter.
	info: CoverageInfo { num_counters: 1, num_expressions: 0 },
	add_missing_operands: false,
	};

	coverage_visitor.visit_body(mir_body);

	coverage_visitor.add_missing_operands = true;
	coverage_visitor.visit_body(mir_body);

	coverage_visitor.info
	}

	fn covered_file_name<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId) -> Option<Symbol> {
	let mir_body = tcx.optimized_mir(def_id);
	for bb_data in mir_body.basic_blocks().iter() {
	for statement in bb_data.statements.iter() {
	if let StatementKind::Coverage(box ref coverage) = statement.kind {
	if let Some(code_region) = coverage.code_region.as_ref() {
	return Some(code_region.file_name);
	}
	}
	}
	}
	None
	}

	fn covered_code_regions<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId) -> Vec<&'tcx CodeRegion> {
	let mir_body: &'tcx mir::Body<'tcx> = tcx.optimized_mir(def_id);
	mir_body
	.basic_blocks()
	.iter()
	.map(\|data\| {
	data.statements.iter().filter_map(\|statement\| match statement.kind {
	StatementKind::Coverage(box ref coverage) => {
	coverage.code_region.as_ref() // may be None
	}
	_ => None,
	})
	})
	.flatten()
	.collect()
	}