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rust/compiler/rustc_mir_transform/src/coverage/debug.rs
Matthias Krüger 2fe9a32ed2 Rollup merge of #90132 - joshtriplett:stabilize-instrument-coverage, r=wesleywiser 
Stabilize `-Z instrument-coverage` as `-C instrument-coverage`

(Tracking issue for `instrument-coverage`: https://github.com/rust-lang/rust/issues/79121)

This PR stabilizes support for instrumentation-based code coverage, previously provided via the `-Z instrument-coverage` option. (Continue supporting `-Z instrument-coverage` for compatibility for now, but show a deprecation warning for it.)

Many, many people have tested this support, and there are numerous reports of it working as expected.

Move the documentation from the unstable book to stable rustc documentation. Update uses and documentation to use the `-C` option.

Addressing questions raised in the tracking issue:

> If/when stabilized, will the compiler flag be updated to -C instrument-coverage? (If so, the -Z variant could also be supported for some time, to ease migrations for existing users and scripts.)

This stabilization PR updates the option to `-C` and keeps the `-Z` variant to ease migration.

> The Rust coverage implementation depends on (and automatically turns on) -Z symbol-mangling-version=v0. Will stabilizing this feature depend on stabilizing v0 symbol-mangling first? If so, what is the current status and timeline?

This stabilization PR depends on https://github.com/rust-lang/rust/pull/90128 , which stabilizes `-C symbol-mangling-version=v0` (but does not change the default symbol-mangling-version).

> The Rust coverage implementation implements the latest version of LLVM's Coverage Mapping Format (version 4), which forces a dependency on LLVM 11 or later. A compiler error is generated if attempting to compile with coverage, and using an older version of LLVM.

Given that LLVM 13 has now been released, requiring LLVM 11 for coverage support seems like a reasonable requirement. If people don't have at least LLVM 11, nothing else breaks; they just can't use coverage support. Given that coverage support currently requires a nightly compiler and LLVM 11 or newer, allowing it on a stable compiler built with LLVM 11 or newer seems like an improvement.

The [tracking issue](https://github.com/rust-lang/rust/issues/79121) and the [issue label A-code-coverage](https://github.com/rust-lang/rust/labels/A-code-coverage) link to a few open issues related to `instrument-coverage`, but none of them seem like showstoppers. All of them seem like improvements and refinements we can make after stabilization.

The original `-Z instrument-coverage` support went through a compiler-team MCP at https://github.com/rust-lang/compiler-team/issues/278 . Based on that, `@pnkfelix` suggested that this needed a stabilization PR and a compiler-team FCP.
2022-02-04 18:42:13 +01:00

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//! The `InstrumentCoverage` MIR pass implementation includes debugging tools and options
//! to help developers understand and/or improve the analysis and instrumentation of a MIR.
//!
//! To enable coverage, include the rustc command line option:
//!
//! * `-C instrument-coverage`
//!
//! MIR Dump Files, with additional `CoverageGraph` graphviz and `CoverageSpan` spanview
//! ------------------------------------------------------------------------------------
//!
//! Additional debugging options include:
//!
//! * `-Z dump-mir=InstrumentCoverage` - Generate `.mir` files showing the state of the MIR,
//! before and after the `InstrumentCoverage` pass, for each compiled function.
//!
//! * `-Z dump-mir-graphviz` - If `-Z dump-mir` is also enabled for the current MIR node path,
//! each MIR dump is accompanied by a before-and-after graphical view of the MIR, in Graphviz
//! `.dot` file format (which can be visually rendered as a graph using any of a number of free
//! Graphviz viewers and IDE extensions).
//!
//! For the `InstrumentCoverage` pass, this option also enables generation of an additional
//! Graphviz `.dot` file for each function, rendering the `CoverageGraph`: the control flow
//! graph (CFG) of `BasicCoverageBlocks` (BCBs), as nodes, internally labeled to show the
//! `CoverageSpan`-based MIR elements each BCB represents (`BasicBlock`s, `Statement`s and
//! `Terminator`s), assigned coverage counters and/or expressions, and edge counters, as needed.
//!
//! (Note the additional option, `-Z graphviz-dark-mode`, can be added, to change the rendered
//! output from its default black-on-white background to a dark color theme, if desired.)
//!
//! * `-Z dump-mir-spanview` - If `-Z dump-mir` is also enabled for the current MIR node path,
//! each MIR dump is accompanied by a before-and-after `.html` document showing the function's
//! original source code, highlighted by it's MIR spans, at the `statement`-level (by default),
//! `terminator` only, or encompassing span for the `Terminator` plus all `Statement`s, in each
//! `block` (`BasicBlock`).
//!
//! For the `InstrumentCoverage` pass, this option also enables generation of an additional
//! spanview `.html` file for each function, showing the aggregated `CoverageSpan`s that will
//! require counters (or counter expressions) for accurate coverage analysis.
//!
//! Debug Logging
//! -------------
//!
//! The `InstrumentCoverage` pass includes debug logging messages at various phases and decision
//! points, which can be enabled via environment variable:
//!
//! ```shell
//! RUSTC_LOG=rustc_mir_transform::transform::coverage=debug
//! ```
//!
//! Other module paths with coverage-related debug logs may also be of interest, particularly for
//! debugging the coverage map data, injected as global variables in the LLVM IR (during rustc's
//! code generation pass). For example:
//!
//! ```shell
//! RUSTC_LOG=rustc_mir_transform::transform::coverage,rustc_codegen_ssa::coverageinfo,rustc_codegen_llvm::coverageinfo=debug
//! ```
//!
//! Coverage Debug Options
//! ---------------------------------
//!
//! Additional debugging options can be enabled using the environment variable:
//!
//! ```shell
//! RUSTC_COVERAGE_DEBUG_OPTIONS=<options>
//! ```
//!
//! These options are comma-separated, and specified in the format `option-name=value`. For example:
//!
//! ```shell
//! $ RUSTC_COVERAGE_DEBUG_OPTIONS=counter-format=id+operation,allow-unused-expressions=yes cargo build
//! ```
//!
//! Coverage debug options include:
//!
//! * `allow-unused-expressions=yes` or `no` (default: `no`)
//!
//! The `InstrumentCoverage` algorithms _should_ only create and assign expressions to a
//! `BasicCoverageBlock`, or an incoming edge, if that expression is either (a) required to
//! count a `CoverageSpan`, or (b) a dependency of some other required counter expression.
//!
//! If an expression is generated that does not map to a `CoverageSpan` or dependency, this
//! probably indicates there was a bug in the algorithm that creates and assigns counters
//! and expressions.
//!
//! When this kind of bug is encountered, the rustc compiler will panic by default. Setting:
//! `allow-unused-expressions=yes` will log a warning message instead of panicking (effectively
//! ignoring the unused expressions), which may be helpful when debugging the root cause of
//! the problem.
//!
//! * `counter-format=<choices>`, where `<choices>` can be any plus-separated combination of `id`,
//! `block`, and/or `operation` (default: `block+operation`)
//!
//! This option effects both the `CoverageGraph` (graphviz `.dot` files) and debug logging, when
//! generating labels for counters and expressions.
//!
//! Depending on the values and combinations, counters can be labeled by:
//!
//! * `id` - counter or expression ID (ascending counter IDs, starting at 1, or descending
//! expression IDs, starting at `u32:MAX`)
//! * `block` - the `BasicCoverageBlock` label (for example, `bcb0`) or edge label (for
//! example `bcb0->bcb1`), for counters or expressions assigned to count a
//! `BasicCoverageBlock` or edge. Intermediate expressions (not directly associated with
//! a BCB or edge) will be labeled by their expression ID, unless `operation` is also
//! specified.
//! * `operation` - applied to expressions only, labels include the left-hand-side counter
//! or expression label (lhs operand), the operator (`+` or `-`), and the right-hand-side
//! counter or expression (rhs operand). Expression operand labels are generated
//! recursively, generating labels with nested operations, enclosed in parentheses
//! (for example: `bcb2 + (bcb0 - bcb1)`).
use super::graph::{BasicCoverageBlock, BasicCoverageBlockData, CoverageGraph};
use super::spans::CoverageSpan;
use itertools::Itertools;
use rustc_middle::mir::create_dump_file;
use rustc_middle::mir::generic_graphviz::GraphvizWriter;
use rustc_middle::mir::spanview::{self, SpanViewable};
use rustc_data_structures::fx::FxHashMap;
use rustc_middle::mir::coverage::*;
use rustc_middle::mir::{self, BasicBlock, TerminatorKind};
use rustc_middle::ty::TyCtxt;
use rustc_span::Span;
use std::iter;
use std::lazy::SyncOnceCell;
pub const NESTED_INDENT: &str = " ";
const RUSTC_COVERAGE_DEBUG_OPTIONS: &str = "RUSTC_COVERAGE_DEBUG_OPTIONS";
pub(super) fn debug_options<'a>() -> &'a DebugOptions {
static DEBUG_OPTIONS: SyncOnceCell<DebugOptions> = SyncOnceCell::new();
&DEBUG_OPTIONS.get_or_init(DebugOptions::from_env)
}
/// Parses and maintains coverage-specific debug options captured from the environment variable
/// "RUSTC_COVERAGE_DEBUG_OPTIONS", if set.
#[derive(Debug, Clone)]
pub(super) struct DebugOptions {
pub allow_unused_expressions: bool,
counter_format: ExpressionFormat,
}
impl DebugOptions {
fn from_env() -> Self {
let mut allow_unused_expressions = true;
let mut counter_format = ExpressionFormat::default();
if let Ok(env_debug_options) = std::env::var(RUSTC_COVERAGE_DEBUG_OPTIONS) {
for setting_str in env_debug_options.replace(' ', "").replace('-', "_").split(',') {
let (option, value) = match setting_str.split_once('=') {
None => (setting_str, None),
Some((k, v)) => (k, Some(v)),
};
match option {
"allow_unused_expressions" => {
allow_unused_expressions = bool_option_val(option, value);
debug!(
"{} env option `allow_unused_expressions` is set to {}",
RUSTC_COVERAGE_DEBUG_OPTIONS, allow_unused_expressions
);
}
"counter_format" => {
match value {
None => {
bug!(
"`{}` option in environment variable {} requires one or more \
plus-separated choices (a non-empty subset of \
`id+block+operation`)",
option,
RUSTC_COVERAGE_DEBUG_OPTIONS
);
}
Some(val) => {
counter_format = counter_format_option_val(val);
debug!(
"{} env option `counter_format` is set to {:?}",
RUSTC_COVERAGE_DEBUG_OPTIONS, counter_format
);
}
};
}
_ => bug!(
"Unsupported setting `{}` in environment variable {}",
option,
RUSTC_COVERAGE_DEBUG_OPTIONS
),
};
}
}
Self { allow_unused_expressions, counter_format }
}
}
fn bool_option_val(option: &str, some_strval: Option<&str>) -> bool {
if let Some(val) = some_strval {
if vec!["yes", "y", "on", "true"].contains(&val) {
true
} else if vec!["no", "n", "off", "false"].contains(&val) {
false
} else {
bug!(
"Unsupported value `{}` for option `{}` in environment variable {}",
option,
val,
RUSTC_COVERAGE_DEBUG_OPTIONS
)
}
} else {
true
}
}
fn counter_format_option_val(strval: &str) -> ExpressionFormat {
let mut counter_format = ExpressionFormat { id: false, block: false, operation: false };
let components = strval.splitn(3, '+');
for component in components {
match component {
"id" => counter_format.id = true,
"block" => counter_format.block = true,
"operation" => counter_format.operation = true,
_ => bug!(
"Unsupported counter_format choice `{}` in environment variable {}",
component,
RUSTC_COVERAGE_DEBUG_OPTIONS
),
}
}
counter_format
}
#[derive(Debug, Clone)]
struct ExpressionFormat {
id: bool,
block: bool,
operation: bool,
}
impl Default for ExpressionFormat {
fn default() -> Self {
Self { id: false, block: true, operation: true }
}
}
/// If enabled, this struct maintains a map from `CoverageKind` IDs (as `ExpressionOperandId`) to
/// the `CoverageKind` data and optional label (normally, the counter's associated
/// `BasicCoverageBlock` format string, if any).
///
/// Use `format_counter` to convert one of these `CoverageKind` counters to a debug output string,
/// as directed by the `DebugOptions`. This allows the format of counter labels in logs and dump
/// files (including the `CoverageGraph` graphviz file) to be changed at runtime, via environment
/// variable.
///
/// `DebugCounters` supports a recursive rendering of `Expression` counters, so they can be
/// presented as nested expressions such as `(bcb3 - (bcb0 + bcb1))`.
pub(super) struct DebugCounters {
some_counters: Option<FxHashMap<ExpressionOperandId, DebugCounter>>,
}
impl DebugCounters {
pub fn new() -> Self {
Self { some_counters: None }
}
pub fn enable(&mut self) {
debug_assert!(!self.is_enabled());
self.some_counters.replace(FxHashMap::default());
}
pub fn is_enabled(&self) -> bool {
self.some_counters.is_some()
}
pub fn add_counter(&mut self, counter_kind: &CoverageKind, some_block_label: Option<String>) {
if let Some(counters) = &mut self.some_counters {
let id: ExpressionOperandId = match *counter_kind {
CoverageKind::Counter { id, .. } => id.into(),
CoverageKind::Expression { id, .. } => id.into(),
_ => bug!(
"the given `CoverageKind` is not an counter or expression: {:?}",
counter_kind
),
};
counters
.try_insert(id, DebugCounter::new(counter_kind.clone(), some_block_label))
.expect("attempt to add the same counter_kind to DebugCounters more than once");
}
}
pub fn some_block_label(&self, operand: ExpressionOperandId) -> Option<&String> {
self.some_counters.as_ref().map_or(None, |counters| {
counters
.get(&operand)
.map_or(None, |debug_counter| debug_counter.some_block_label.as_ref())
})
}
pub fn format_counter(&self, counter_kind: &CoverageKind) -> String {
match *counter_kind {
CoverageKind::Counter { .. } => {
format!("Counter({})", self.format_counter_kind(counter_kind))
}
CoverageKind::Expression { .. } => {
format!("Expression({})", self.format_counter_kind(counter_kind))
}
CoverageKind::Unreachable { .. } => "Unreachable".to_owned(),
}
}
fn format_counter_kind(&self, counter_kind: &CoverageKind) -> String {
let counter_format = &debug_options().counter_format;
if let CoverageKind::Expression { id, lhs, op, rhs } = *counter_kind {
if counter_format.operation {
return format!(
"{}{} {} {}",
if counter_format.id || self.some_counters.is_none() {
format!("#{} = ", id.index())
} else {
String::new()
},
self.format_operand(lhs),
if op == Op::Add { "+" } else { "-" },
self.format_operand(rhs),
);
}
}
let id: ExpressionOperandId = match *counter_kind {
CoverageKind::Counter { id, .. } => id.into(),
CoverageKind::Expression { id, .. } => id.into(),
_ => {
bug!("the given `CoverageKind` is not an counter or expression: {:?}", counter_kind)
}
};
if self.some_counters.is_some() && (counter_format.block || !counter_format.id) {
let counters = self.some_counters.as_ref().unwrap();
if let Some(DebugCounter { some_block_label: Some(block_label), .. }) =
counters.get(&id)
{
return if counter_format.id {
format!("{}#{}", block_label, id.index())
} else {
block_label.to_string()
};
}
}
format!("#{}", id.index())
}
fn format_operand(&self, operand: ExpressionOperandId) -> String {
if operand.index() == 0 {
return String::from("0");
}
if let Some(counters) = &self.some_counters {
if let Some(DebugCounter { counter_kind, some_block_label }) = counters.get(&operand) {
if let CoverageKind::Expression { .. } = counter_kind {
if let Some(block_label) = some_block_label {
if debug_options().counter_format.block {
return format!(
"{}:({})",
block_label,
self.format_counter_kind(counter_kind)
);
}
}
return format!("({})", self.format_counter_kind(counter_kind));
}
return self.format_counter_kind(counter_kind);
}
}
format!("#{}", operand.index())
}
}
/// A non-public support class to `DebugCounters`.
#[derive(Debug)]
struct DebugCounter {
counter_kind: CoverageKind,
some_block_label: Option<String>,
}
impl DebugCounter {
fn new(counter_kind: CoverageKind, some_block_label: Option<String>) -> Self {
Self { counter_kind, some_block_label }
}
}
/// If enabled, this data structure captures additional debugging information used when generating
/// a Graphviz (.dot file) representation of the `CoverageGraph`, for debugging purposes.
pub(super) struct GraphvizData {
some_bcb_to_coverage_spans_with_counters:
Option<FxHashMap<BasicCoverageBlock, Vec<(CoverageSpan, CoverageKind)>>>,
some_bcb_to_dependency_counters: Option<FxHashMap<BasicCoverageBlock, Vec<CoverageKind>>>,
some_edge_to_counter: Option<FxHashMap<(BasicCoverageBlock, BasicBlock), CoverageKind>>,
}
impl GraphvizData {
pub fn new() -> Self {
Self {
some_bcb_to_coverage_spans_with_counters: None,
some_bcb_to_dependency_counters: None,
some_edge_to_counter: None,
}
}
pub fn enable(&mut self) {
debug_assert!(!self.is_enabled());
self.some_bcb_to_coverage_spans_with_counters = Some(FxHashMap::default());
self.some_bcb_to_dependency_counters = Some(FxHashMap::default());
self.some_edge_to_counter = Some(FxHashMap::default());
}
pub fn is_enabled(&self) -> bool {
self.some_bcb_to_coverage_spans_with_counters.is_some()
}
pub fn add_bcb_coverage_span_with_counter(
&mut self,
bcb: BasicCoverageBlock,
coverage_span: &CoverageSpan,
counter_kind: &CoverageKind,
) {
if let Some(bcb_to_coverage_spans_with_counters) =
self.some_bcb_to_coverage_spans_with_counters.as_mut()
{
bcb_to_coverage_spans_with_counters
.entry(bcb)
.or_insert_with(Vec::new)
.push((coverage_span.clone(), counter_kind.clone()));
}
}
pub fn get_bcb_coverage_spans_with_counters(
&self,
bcb: BasicCoverageBlock,
) -> Option<&Vec<(CoverageSpan, CoverageKind)>> {
if let Some(bcb_to_coverage_spans_with_counters) =
self.some_bcb_to_coverage_spans_with_counters.as_ref()
{
bcb_to_coverage_spans_with_counters.get(&bcb)
} else {
None
}
}
pub fn add_bcb_dependency_counter(
&mut self,
bcb: BasicCoverageBlock,
counter_kind: &CoverageKind,
) {
if let Some(bcb_to_dependency_counters) = self.some_bcb_to_dependency_counters.as_mut() {
bcb_to_dependency_counters
.entry(bcb)
.or_insert_with(Vec::new)
.push(counter_kind.clone());
}
}
pub fn get_bcb_dependency_counters(
&self,
bcb: BasicCoverageBlock,
) -> Option<&Vec<CoverageKind>> {
if let Some(bcb_to_dependency_counters) = self.some_bcb_to_dependency_counters.as_ref() {
bcb_to_dependency_counters.get(&bcb)
} else {
None
}
}
pub fn set_edge_counter(
&mut self,
from_bcb: BasicCoverageBlock,
to_bb: BasicBlock,
counter_kind: &CoverageKind,
) {
if let Some(edge_to_counter) = self.some_edge_to_counter.as_mut() {
edge_to_counter
.try_insert((from_bcb, to_bb), counter_kind.clone())
.expect("invalid attempt to insert more than one edge counter for the same edge");
}
}
pub fn get_edge_counter(
&self,
from_bcb: BasicCoverageBlock,
to_bb: BasicBlock,
) -> Option<&CoverageKind> {
if let Some(edge_to_counter) = self.some_edge_to_counter.as_ref() {
edge_to_counter.get(&(from_bcb, to_bb))
} else {
None
}
}
}
/// If enabled, this struct captures additional data used to track whether expressions were used,
/// directly or indirectly, to compute the coverage counts for all `CoverageSpan`s, and any that are
/// _not_ used are retained in the `unused_expressions` Vec, to be included in debug output (logs
/// and/or a `CoverageGraph` graphviz output).
pub(super) struct UsedExpressions {
some_used_expression_operands:
Option<FxHashMap<ExpressionOperandId, Vec<InjectedExpressionId>>>,
some_unused_expressions:
Option<Vec<(CoverageKind, Option<BasicCoverageBlock>, BasicCoverageBlock)>>,
}
impl UsedExpressions {
pub fn new() -> Self {
Self { some_used_expression_operands: None, some_unused_expressions: None }
}
pub fn enable(&mut self) {
debug_assert!(!self.is_enabled());
self.some_used_expression_operands = Some(FxHashMap::default());
self.some_unused_expressions = Some(Vec::new());
}
pub fn is_enabled(&self) -> bool {
self.some_used_expression_operands.is_some()
}
pub fn add_expression_operands(&mut self, expression: &CoverageKind) {
if let Some(used_expression_operands) = self.some_used_expression_operands.as_mut() {
if let CoverageKind::Expression { id, lhs, rhs, .. } = *expression {
used_expression_operands.entry(lhs).or_insert_with(Vec::new).push(id);
used_expression_operands.entry(rhs).or_insert_with(Vec::new).push(id);
}
}
}
pub fn expression_is_used(&self, expression: &CoverageKind) -> bool {
if let Some(used_expression_operands) = self.some_used_expression_operands.as_ref() {
used_expression_operands.contains_key(&expression.as_operand_id())
} else {
false
}
}
pub fn add_unused_expression_if_not_found(
&mut self,
expression: &CoverageKind,
edge_from_bcb: Option<BasicCoverageBlock>,
target_bcb: BasicCoverageBlock,
) {
if let Some(used_expression_operands) = self.some_used_expression_operands.as_ref() {
if !used_expression_operands.contains_key(&expression.as_operand_id()) {
self.some_unused_expressions.as_mut().unwrap().push((
expression.clone(),
edge_from_bcb,
target_bcb,
));
}
}
}
/// Return the list of unused counters (if any) as a tuple with the counter (`CoverageKind`),
/// optional `from_bcb` (if it was an edge counter), and `target_bcb`.
pub fn get_unused_expressions(
&self,
) -> Vec<(CoverageKind, Option<BasicCoverageBlock>, BasicCoverageBlock)> {
if let Some(unused_expressions) = self.some_unused_expressions.as_ref() {
unused_expressions.clone()
} else {
Vec::new()
}
}
/// If enabled, validate that every BCB or edge counter not directly associated with a coverage
/// span is at least indirectly associated (it is a dependency of a BCB counter that _is_
/// associated with a coverage span).
pub fn validate(
&mut self,
bcb_counters_without_direct_coverage_spans: &Vec<(
Option<BasicCoverageBlock>,
BasicCoverageBlock,
CoverageKind,
)>,
) {
if self.is_enabled() {
let mut not_validated = bcb_counters_without_direct_coverage_spans
.iter()
.map(|(_, _, counter_kind)| counter_kind)
.collect::<Vec<_>>();
let mut validating_count = 0;
while not_validated.len() != validating_count {
let to_validate = not_validated.split_off(0);
validating_count = to_validate.len();
for counter_kind in to_validate {
if self.expression_is_used(counter_kind) {
self.add_expression_operands(counter_kind);
} else {
not_validated.push(counter_kind);
}
}
}
}
}
pub fn alert_on_unused_expressions(&self, debug_counters: &DebugCounters) {
if let Some(unused_expressions) = self.some_unused_expressions.as_ref() {
for (counter_kind, edge_from_bcb, target_bcb) in unused_expressions {
let unused_counter_message = if let Some(from_bcb) = edge_from_bcb.as_ref() {
format!(
"non-coverage edge counter found without a dependent expression, in \
{:?}->{:?}; counter={}",
from_bcb,
target_bcb,
debug_counters.format_counter(&counter_kind),
)
} else {
format!(
"non-coverage counter found without a dependent expression, in {:?}; \
counter={}",
target_bcb,
debug_counters.format_counter(&counter_kind),
)
};
if debug_options().allow_unused_expressions {
debug!("WARNING: {}", unused_counter_message);
} else {
bug!("{}", unused_counter_message);
}
}
}
}
}
/// Generates the MIR pass `CoverageSpan`-specific spanview dump file.
pub(super) fn dump_coverage_spanview<'tcx>(
tcx: TyCtxt<'tcx>,
mir_body: &mir::Body<'tcx>,
basic_coverage_blocks: &CoverageGraph,
pass_name: &str,
body_span: Span,
coverage_spans: &Vec<CoverageSpan>,
) {
let mir_source = mir_body.source;
let def_id = mir_source.def_id();
let span_viewables = span_viewables(tcx, mir_body, basic_coverage_blocks, &coverage_spans);
let mut file = create_dump_file(tcx, "html", None, pass_name, &0, mir_source)
.expect("Unexpected error creating MIR spanview HTML file");
let crate_name = tcx.crate_name(def_id.krate);
let item_name = tcx.def_path(def_id).to_filename_friendly_no_crate();
let title = format!("{}.{} - Coverage Spans", crate_name, item_name);
spanview::write_document(tcx, body_span, span_viewables, &title, &mut file)
.expect("Unexpected IO error dumping coverage spans as HTML");
}
/// Converts the computed `BasicCoverageBlockData`s into `SpanViewable`s.
fn span_viewables<'tcx>(
tcx: TyCtxt<'tcx>,
mir_body: &mir::Body<'tcx>,
basic_coverage_blocks: &CoverageGraph,
coverage_spans: &Vec<CoverageSpan>,
) -> Vec<SpanViewable> {
let mut span_viewables = Vec::new();
for coverage_span in coverage_spans {
let tooltip = coverage_span.format_coverage_statements(tcx, mir_body);
let CoverageSpan { span, bcb, .. } = coverage_span;
let bcb_data = &basic_coverage_blocks[*bcb];
let id = bcb_data.id();
let leader_bb = bcb_data.leader_bb();
span_viewables.push(SpanViewable { bb: leader_bb, span: *span, id, tooltip });
}
span_viewables
}
/// Generates the MIR pass coverage-specific graphviz dump file.
pub(super) fn dump_coverage_graphviz<'tcx>(
tcx: TyCtxt<'tcx>,
mir_body: &mir::Body<'tcx>,
pass_name: &str,
basic_coverage_blocks: &CoverageGraph,
debug_counters: &DebugCounters,
graphviz_data: &GraphvizData,
intermediate_expressions: &Vec<CoverageKind>,
debug_used_expressions: &UsedExpressions,
) {
let mir_source = mir_body.source;
let def_id = mir_source.def_id();
let node_content = |bcb| {
bcb_to_string_sections(
tcx,
mir_body,
debug_counters,
&basic_coverage_blocks[bcb],
graphviz_data.get_bcb_coverage_spans_with_counters(bcb),
graphviz_data.get_bcb_dependency_counters(bcb),
// intermediate_expressions are injected into the mir::START_BLOCK, so
// include them in the first BCB.
if bcb.index() == 0 { Some(&intermediate_expressions) } else { None },
)
};
let edge_labels = |from_bcb| {
let from_bcb_data = &basic_coverage_blocks[from_bcb];
let from_terminator = from_bcb_data.terminator(mir_body);
let mut edge_labels = from_terminator.kind.fmt_successor_labels();
edge_labels.retain(|label| label != "unreachable");
let edge_counters = from_terminator
.successors()
.map(|&successor_bb| graphviz_data.get_edge_counter(from_bcb, successor_bb));
iter::zip(&edge_labels, edge_counters)
.map(|(label, some_counter)| {
if let Some(counter) = some_counter {
format!("{}\n{}", label, debug_counters.format_counter(counter))
} else {
label.to_string()
}
})
.collect::<Vec<_>>()
};
let graphviz_name = format!("Cov_{}_{}", def_id.krate.index(), def_id.index.index());
let mut graphviz_writer =
GraphvizWriter::new(basic_coverage_blocks, &graphviz_name, node_content, edge_labels);
let unused_expressions = debug_used_expressions.get_unused_expressions();
if unused_expressions.len() > 0 {
graphviz_writer.set_graph_label(&format!(
"Unused expressions:\n {}",
unused_expressions
.as_slice()
.iter()
.map(|(counter_kind, edge_from_bcb, target_bcb)| {
if let Some(from_bcb) = edge_from_bcb.as_ref() {
format!(
"{:?}->{:?}: {}",
from_bcb,
target_bcb,
debug_counters.format_counter(&counter_kind),
)
} else {
format!(
"{:?}: {}",
target_bcb,
debug_counters.format_counter(&counter_kind),
)
}
})
.join("\n ")
));
}
let mut file = create_dump_file(tcx, "dot", None, pass_name, &0, mir_source)
.expect("Unexpected error creating BasicCoverageBlock graphviz DOT file");
graphviz_writer
.write_graphviz(tcx, &mut file)
.expect("Unexpected error writing BasicCoverageBlock graphviz DOT file");
}
fn bcb_to_string_sections<'tcx>(
tcx: TyCtxt<'tcx>,
mir_body: &mir::Body<'tcx>,
debug_counters: &DebugCounters,
bcb_data: &BasicCoverageBlockData,
some_coverage_spans_with_counters: Option<&Vec<(CoverageSpan, CoverageKind)>>,
some_dependency_counters: Option<&Vec<CoverageKind>>,
some_intermediate_expressions: Option<&Vec<CoverageKind>>,
) -> Vec<String> {
let len = bcb_data.basic_blocks.len();
let mut sections = Vec::new();
if let Some(collect_intermediate_expressions) = some_intermediate_expressions {
sections.push(
collect_intermediate_expressions
.iter()
.map(|expression| {
format!("Intermediate {}", debug_counters.format_counter(expression))
})
.join("\n"),
);
}
if let Some(coverage_spans_with_counters) = some_coverage_spans_with_counters {
sections.push(
coverage_spans_with_counters
.iter()
.map(|(covspan, counter)| {
format!(
"{} at {}",
debug_counters.format_counter(counter),
covspan.format(tcx, mir_body)
)
})
.join("\n"),
);
}
if let Some(dependency_counters) = some_dependency_counters {
sections.push(format!(
"Non-coverage counters:\n {}",
dependency_counters
.iter()
.map(|counter| debug_counters.format_counter(counter))
.join(" \n"),
));
}
if let Some(counter_kind) = &bcb_data.counter_kind {
sections.push(format!("{:?}", counter_kind));
}
let non_term_blocks = bcb_data.basic_blocks[0..len - 1]
.iter()
.map(|&bb| format!("{:?}: {}", bb, term_type(&mir_body[bb].terminator().kind)))
.collect::<Vec<_>>();
if non_term_blocks.len() > 0 {
sections.push(non_term_blocks.join("\n"));
}
sections.push(format!(
"{:?}: {}",
bcb_data.basic_blocks.last().unwrap(),
term_type(&bcb_data.terminator(mir_body).kind)
));
sections
}
/// Returns a simple string representation of a `TerminatorKind` variant, independent of any
/// values it might hold.
pub(super) fn term_type(kind: &TerminatorKind<'_>) -> &'static str {
match kind {
TerminatorKind::Goto { .. } => "Goto",
TerminatorKind::SwitchInt { .. } => "SwitchInt",
TerminatorKind::Resume => "Resume",
TerminatorKind::Abort => "Abort",
TerminatorKind::Return => "Return",
TerminatorKind::Unreachable => "Unreachable",
TerminatorKind::Drop { .. } => "Drop",
TerminatorKind::DropAndReplace { .. } => "DropAndReplace",
TerminatorKind::Call { .. } => "Call",
TerminatorKind::Assert { .. } => "Assert",
TerminatorKind::Yield { .. } => "Yield",
TerminatorKind::GeneratorDrop => "GeneratorDrop",
TerminatorKind::FalseEdge { .. } => "FalseEdge",
TerminatorKind::FalseUnwind { .. } => "FalseUnwind",
TerminatorKind::InlineAsm { .. } => "InlineAsm",
}
}
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