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use crate::coverageinfo::ffi::{Counter, CounterExpression, ExprKind};
use rustc_data_structures::fx::FxIndexSet;
use rustc_index::bit_set::BitSet;
use rustc_index::IndexVec;
use rustc_middle::mir::coverage::{
CodeRegion, CounterId, CovTerm, ExpressionId, FunctionCoverageInfo, Mapping, Op,
};
use rustc_middle::ty::Instance;
#[derive(Clone, Debug, PartialEq)]
pub struct Expression {
lhs: CovTerm,
op: Op,
rhs: CovTerm,
}
/// Holds all of the coverage mapping data associated with a function instance,
/// collected during traversal of `Coverage` statements in the function's MIR.
#[derive(Debug)]
pub struct FunctionCoverage<'tcx> {
/// Coverage info that was attached to this function by the instrumentor.
function_coverage_info: &'tcx FunctionCoverageInfo,
is_used: bool,
/// Tracks which counters have been seen, to avoid duplicate mappings
/// that might be introduced by MIR inlining.
counters_seen: BitSet<CounterId>,
expressions: IndexVec<ExpressionId, Option<Expression>>,
mappings: Vec<Mapping>,
}
impl<'tcx> FunctionCoverage<'tcx> {
/// Creates a new set of coverage data for a used (called) function.
pub fn new(
instance: Instance<'tcx>,
function_coverage_info: &'tcx FunctionCoverageInfo,
) -> Self {
Self::create(instance, function_coverage_info, true)
}
/// Creates a new set of coverage data for an unused (never called) function.
pub fn unused(
instance: Instance<'tcx>,
function_coverage_info: &'tcx FunctionCoverageInfo,
) -> Self {
Self::create(instance, function_coverage_info, false)
}
fn create(
instance: Instance<'tcx>,
function_coverage_info: &'tcx FunctionCoverageInfo,
is_used: bool,
) -> Self {
let num_counters = function_coverage_info.num_counters;
let num_expressions = function_coverage_info.num_expressions;
debug!(
"FunctionCoverage::create(instance={instance:?}) has \
num_counters={num_counters}, num_expressions={num_expressions}, is_used={is_used}"
);
Self {
function_coverage_info,
is_used,
counters_seen: BitSet::new_empty(num_counters),
expressions: IndexVec::from_elem_n(None, num_expressions),
mappings: Vec::new(),
}
}
/// Returns true for a used (called) function, and false for an unused function.
pub fn is_used(&self) -> bool {
self.is_used
}
/// Adds code regions to be counted by an injected counter intrinsic.
#[instrument(level = "debug", skip(self))]
pub(crate) fn add_counter(&mut self, id: CounterId, code_regions: &[CodeRegion]) {
if self.counters_seen.insert(id) {
self.add_mappings(CovTerm::Counter(id), code_regions);
}
}
/// Adds information about a coverage expression, along with zero or more
/// code regions mapped to that expression.
///
/// Both counters and "counter expressions" (or simply, "expressions") can be operands in other
/// expressions. These are tracked as separate variants of `CovTerm`, so there is no ambiguity
/// between operands that are counter IDs and operands that are expression IDs.
#[instrument(level = "debug", skip(self))]
pub(crate) fn add_counter_expression(
&mut self,
expression_id: ExpressionId,
lhs: CovTerm,
op: Op,
rhs: CovTerm,
code_regions: &[CodeRegion],
) {
debug_assert!(
expression_id.as_usize() < self.expressions.len(),
"expression_id {} is out of range for expressions.len() = {}
for {:?}",
expression_id.as_usize(),
self.expressions.len(),
self,
);
let expression = Expression { lhs, op, rhs };
let slot = &mut self.expressions[expression_id];
match slot {
None => {
*slot = Some(expression);
self.add_mappings(CovTerm::Expression(expression_id), code_regions);
}
// If this expression ID slot has already been filled, it should
// contain identical information.
Some(ref previous_expression) => assert_eq!(
previous_expression, &expression,
"add_counter_expression: expression for id changed"
),
}
}
/// Adds regions that will be marked as "unreachable", with a constant "zero counter".
#[instrument(level = "debug", skip(self))]
pub(crate) fn add_unreachable_regions(&mut self, code_regions: &[CodeRegion]) {
assert!(!code_regions.is_empty(), "unreachable regions always have code regions");
self.add_mappings(CovTerm::Zero, code_regions);
}
#[instrument(level = "debug", skip(self))]
fn add_mappings(&mut self, term: CovTerm, code_regions: &[CodeRegion]) {
self.mappings
.extend(code_regions.iter().cloned().map(|code_region| Mapping { term, code_region }));
}
pub(crate) fn finalize(&mut self) {
self.simplify_expressions();
// Reorder the collected mappings so that counter mappings are first and
// zero mappings are last, matching the historical order.
self.mappings.sort_by_key(|mapping| match mapping.term {
CovTerm::Counter(_) => 0,
CovTerm::Expression(_) => 1,
CovTerm::Zero => u8::MAX,
});
}
/// Perform some simplifications to make the final coverage mappings
/// slightly smaller.
///
/// This method mainly exists to preserve the simplifications that were
/// already being performed by the Rust-side expression renumbering, so that
/// the resulting coverage mappings don't get worse.
fn simplify_expressions(&mut self) {
// The set of expressions that either were optimized out entirely, or
// have zero as both of their operands, and will therefore always have
// a value of zero. Other expressions that refer to these as operands
// can have those operands replaced with `CovTerm::Zero`.
let mut zero_expressions = FxIndexSet::default();
// For each expression, perform simplifications based on lower-numbered
// expressions, and then update the set of always-zero expressions if
// necessary.
// (By construction, expressions can only refer to other expressions
// that have lower IDs, so one simplification pass is sufficient.)
for (id, maybe_expression) in self.expressions.iter_enumerated_mut() {
let Some(expression) = maybe_expression else {
// If an expression is missing, it must have been optimized away,
// so any operand that refers to it can be replaced with zero.
zero_expressions.insert(id);
continue;
};
// If an operand refers to an expression that is always zero, then
// that operand can be replaced with `CovTerm::Zero`.
let maybe_set_operand_to_zero = |operand: &mut CovTerm| match &*operand {
CovTerm::Expression(id) if zero_expressions.contains(id) => {
*operand = CovTerm::Zero;
}
_ => (),
};
maybe_set_operand_to_zero(&mut expression.lhs);
maybe_set_operand_to_zero(&mut expression.rhs);
// Coverage counter values cannot be negative, so if an expression
// involves subtraction from zero, assume that its RHS must also be zero.
// (Do this after simplifications that could set the LHS to zero.)
if let Expression { lhs: CovTerm::Zero, op: Op::Subtract, .. } = expression {
expression.rhs = CovTerm::Zero;
}
// After the above simplifications, if both operands are zero, then
// we know that this expression is always zero too.
if let Expression { lhs: CovTerm::Zero, rhs: CovTerm::Zero, .. } = expression {
zero_expressions.insert(id);
}
}
}
/// Return the source hash, generated from the HIR node structure, and used to indicate whether
/// or not the source code structure changed between different compilations.
pub fn source_hash(&self) -> u64 {
if self.is_used { self.function_coverage_info.function_source_hash } else { 0 }
}
/// Generate an array of CounterExpressions, and an iterator over all `Counter`s and their
/// associated `Regions` (from which the LLVM-specific `CoverageMapGenerator` will create
/// `CounterMappingRegion`s.
pub fn get_expressions_and_counter_regions(
&self,
) -> (Vec<CounterExpression>, impl Iterator<Item = (Counter, &CodeRegion)>) {
let counter_expressions = self.counter_expressions();
// Expression IDs are indices into `self.expressions`, and on the LLVM
// side they will be treated as indices into `counter_expressions`, so
// the two vectors should correspond 1:1.
assert_eq!(self.expressions.len(), counter_expressions.len());
let counter_regions = self.counter_regions();
(counter_expressions, counter_regions)
}
/// Convert this function's coverage expression data into a form that can be
/// passed through FFI to LLVM.
fn counter_expressions(&self) -> Vec<CounterExpression> {
// We know that LLVM will optimize out any unused expressions before
// producing the final coverage map, so there's no need to do the same
// thing on the Rust side unless we're confident we can do much better.
// (See `CounterExpressionsMinimizer` in `CoverageMappingWriter.cpp`.)
self.expressions
.iter()
.map(|expression| match expression {
None => {
// This expression ID was allocated, but we never saw the
// actual expression, so it must have been optimized out.
// Replace it with a dummy expression, and let LLVM take
// care of omitting it from the expression list.
CounterExpression::DUMMY
}
&Some(Expression { lhs, op, rhs, .. }) => {
// Convert the operands and operator as normal.
CounterExpression::new(
Counter::from_term(lhs),
match op {
Op::Add => ExprKind::Add,
Op::Subtract => ExprKind::Subtract,
},
Counter::from_term(rhs),
)
}
})
.collect::<Vec<_>>()
}
/// Converts this function's coverage mappings into an intermediate form
/// that will be used by `mapgen` when preparing for FFI.
fn counter_regions(&self) -> impl Iterator<Item = (Counter, &CodeRegion)> {
self.mappings.iter().map(|&Mapping { term, ref code_region }| {
let counter = Counter::from_term(term);
(counter, code_region)
})
}
}
|
