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denoland-deno/cli/tools/coverage.rs

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// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license.
use crate::ast;
use crate::ast::TokenOrComment;
use crate::colors;
use crate::flags::Flags;
use crate::fs_util::collect_files;
use crate::media_type::MediaType;
use crate::module_graph::TypeLib;
use crate::program_state::ProgramState;
use crate::source_maps::SourceMapGetter;
use deno_core::error::AnyError;
use deno_core::serde_json;
use deno_core::serde_json::json;
use deno_core::url::Url;
use deno_core::LocalInspectorSession;
use deno_runtime::permissions::Permissions;
use regex::Regex;
use serde::Deserialize;
use serde::Serialize;
use sourcemap::SourceMap;
use std::fs;
use std::path::PathBuf;
use swc_common::Span;
use uuid::Uuid;
pub struct CoverageCollector {
pub dir: PathBuf,
refactor: Rewrite Inspector implementation (#10725) This commit refactors implementation of inspector. The intention is to be able to move inspector implementation to "deno_core". Following things were done to make that possible: * "runtime/inspector.rs" was split into "runtime/inspector/mod.rs" and "runtime/inspector/server.rs", separating inspector implementation from Websocket server implementation. * "DenoInspector" was renamed to "JsRuntimeInspector" and reference to "server" was removed from the structure, making it independent of Websocket server used to connect to Chrome Devtools. * "WebsocketSession" was renamed to "InspectorSession" and rewritten in such a way that it's not tied to Websockets anymore; instead it accepts a pair of "proxy" channel ends that allow to integrate the session with different "transports". * "InspectorSession" was renamed to "LocalInspectorSession" to better indicate that it's an "in-memory" session and doesn't require Websocket server. It was also rewritten in such a way that it uses "InspectorSession" from previous point instead of reimplementing "v8::inspector::ChannelImpl" trait; this is done by using the "proxy" channels to communicate with the V8 session. Consequently "LocalInspectorSession" is now a frontend to "InspectorSession". This introduces a small inconvenience that awaiting responses for "LocalInspectorSession" requires to concurrently poll worker's event loop. This arises from the fact that "InspectorSession" is now owned by "JsRuntimeInspector", which in turn is owned by "Worker" or "WebWorker". To ease this situation "Worker::with_event_loop" helper method was added, that takes a future and concurrently polls it along with the event loop (using "tokio::select!" macro inside a loop).
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session: LocalInspectorSession,
}
impl CoverageCollector {
refactor: Rewrite Inspector implementation (#10725) This commit refactors implementation of inspector. The intention is to be able to move inspector implementation to "deno_core". Following things were done to make that possible: * "runtime/inspector.rs" was split into "runtime/inspector/mod.rs" and "runtime/inspector/server.rs", separating inspector implementation from Websocket server implementation. * "DenoInspector" was renamed to "JsRuntimeInspector" and reference to "server" was removed from the structure, making it independent of Websocket server used to connect to Chrome Devtools. * "WebsocketSession" was renamed to "InspectorSession" and rewritten in such a way that it's not tied to Websockets anymore; instead it accepts a pair of "proxy" channel ends that allow to integrate the session with different "transports". * "InspectorSession" was renamed to "LocalInspectorSession" to better indicate that it's an "in-memory" session and doesn't require Websocket server. It was also rewritten in such a way that it uses "InspectorSession" from previous point instead of reimplementing "v8::inspector::ChannelImpl" trait; this is done by using the "proxy" channels to communicate with the V8 session. Consequently "LocalInspectorSession" is now a frontend to "InspectorSession". This introduces a small inconvenience that awaiting responses for "LocalInspectorSession" requires to concurrently poll worker's event loop. This arises from the fact that "InspectorSession" is now owned by "JsRuntimeInspector", which in turn is owned by "Worker" or "WebWorker". To ease this situation "Worker::with_event_loop" helper method was added, that takes a future and concurrently polls it along with the event loop (using "tokio::select!" macro inside a loop).
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pub fn new(dir: PathBuf, session: LocalInspectorSession) -> Self {
Self { dir, session }
}
pub async fn start_collecting(&mut self) -> Result<(), AnyError> {
self.session.post_message("Debugger.enable", None).await?;
self.session.post_message("Profiler.enable", None).await?;
self
.session
.post_message(
"Profiler.startPreciseCoverage",
Some(json!({"callCount": true, "detailed": true})),
)
.await?;
Ok(())
}
pub async fn stop_collecting(&mut self) -> Result<(), AnyError> {
let result = self
.session
.post_message("Profiler.takePreciseCoverage", None)
.await?;
let take_coverage_result: TakePreciseCoverageResult =
serde_json::from_value(result)?;
fs::create_dir_all(&self.dir)?;
let script_coverages = take_coverage_result.result;
for script_coverage in script_coverages {
let filename = format!("{}.json", Uuid::new_v4());
let json = serde_json::to_string(&script_coverage)?;
fs::write(self.dir.join(filename), &json)?;
}
self.session.post_message("Profiler.disable", None).await?;
self.session.post_message("Debugger.disable", None).await?;
Ok(())
}
}
// TODO(caspervonb) all of these structs can and should be made private, possibly moved to
// inspector::protocol.
#[derive(Debug, Serialize, Deserialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct CoverageRange {
pub start_offset: usize,
pub end_offset: usize,
pub count: usize,
}
#[derive(Debug, Serialize, Deserialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct FunctionCoverage {
pub function_name: String,
pub ranges: Vec<CoverageRange>,
pub is_block_coverage: bool,
}
#[derive(Debug, Serialize, Deserialize, Clone)]
#[serde(rename_all = "camelCase")]
pub struct ScriptCoverage {
pub script_id: String,
pub url: String,
pub functions: Vec<FunctionCoverage>,
}
#[derive(Debug, Serialize, Deserialize)]
#[serde(rename_all = "camelCase")]
struct TakePreciseCoverageResult {
result: Vec<ScriptCoverage>,
}
#[derive(Debug, Deserialize)]
#[serde(rename_all = "camelCase")]
pub struct GetScriptSourceResult {
pub script_source: String,
pub bytecode: Option<String>,
}
pub enum CoverageReporterKind {
Pretty,
Lcov,
}
fn create_reporter(
kind: CoverageReporterKind,
) -> Box<dyn CoverageReporter + Send> {
match kind {
CoverageReporterKind::Lcov => Box::new(LcovCoverageReporter::new()),
CoverageReporterKind::Pretty => Box::new(PrettyCoverageReporter::new()),
}
}
pub trait CoverageReporter {
fn visit_coverage(
&mut self,
script_coverage: &ScriptCoverage,
script_source: &str,
maybe_source_map: Option<Vec<u8>>,
maybe_original_source: Option<String>,
);
fn done(&mut self);
}
pub struct LcovCoverageReporter {}
impl LcovCoverageReporter {
pub fn new() -> LcovCoverageReporter {
LcovCoverageReporter {}
}
}
impl CoverageReporter for LcovCoverageReporter {
fn visit_coverage(
&mut self,
script_coverage: &ScriptCoverage,
script_source: &str,
maybe_source_map: Option<Vec<u8>>,
_maybe_original_source: Option<String>,
) {
// TODO(caspervonb) cleanup and reduce duplication between reporters, pre-compute line coverage
// elsewhere.
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let maybe_source_map = maybe_source_map
.map(|source_map| SourceMap::from_slice(&source_map).unwrap());
let url = Url::parse(&script_coverage.url).unwrap();
let file_path = url.to_file_path().unwrap();
println!("SF:{}", file_path.to_str().unwrap());
let mut functions_found = 0;
for function in &script_coverage.functions {
if function.function_name.is_empty() {
continue;
}
let source_line = script_source[0..function.ranges[0].start_offset]
.split('\n')
.count();
let line_index = if let Some(source_map) = maybe_source_map.as_ref() {
source_map
.tokens()
.find(|token| token.get_dst_line() as usize == source_line)
.map(|token| token.get_src_line() as usize)
.unwrap_or(0)
} else {
source_line
};
let function_name = &function.function_name;
println!("FN:{},{}", line_index + 1, function_name);
functions_found += 1;
}
let mut functions_hit = 0;
for function in &script_coverage.functions {
if function.function_name.is_empty() {
continue;
}
let execution_count = function.ranges[0].count;
let function_name = &function.function_name;
println!("FNDA:{},{}", execution_count, function_name);
if execution_count != 0 {
functions_hit += 1;
}
}
println!("FNF:{}", functions_found);
println!("FNH:{}", functions_hit);
let mut branches_found = 0;
let mut branches_hit = 0;
for (block_number, function) in script_coverage.functions.iter().enumerate()
{
let block_hits = function.ranges[0].count;
for (branch_number, range) in function.ranges[1..].iter().enumerate() {
let source_line =
script_source[0..range.start_offset].split('\n').count();
let line_index = if let Some(source_map) = maybe_source_map.as_ref() {
source_map
.tokens()
.find(|token| token.get_dst_line() as usize == source_line)
.map(|token| token.get_src_line() as usize)
.unwrap_or(0)
} else {
source_line
};
// From https://manpages.debian.org/unstable/lcov/geninfo.1.en.html:
//
// Block number and branch number are gcc internal IDs for the branch. Taken is either '-'
// if the basic block containing the branch was never executed or a number indicating how
// often that branch was taken.
//
// However with the data we get from v8 coverage profiles it seems we can't actually hit
// this as appears it won't consider any nested branches it hasn't seen but its here for
// the sake of accuracy.
let taken = if block_hits > 0 {
range.count.to_string()
} else {
"-".to_string()
};
println!(
"BRDA:{},{},{},{}",
line_index + 1,
block_number,
branch_number,
taken
);
branches_found += 1;
if range.count > 0 {
branches_hit += 1;
}
}
}
println!("BRF:{}", branches_found);
println!("BRH:{}", branches_hit);
let lines = script_source.split('\n').collect::<Vec<_>>();
let line_offsets = {
let mut offsets: Vec<(usize, usize)> = Vec::new();
let mut index = 0;
for line in &lines {
offsets.push((index, index + line.len() + 1));
index += line.len() + 1;
}
offsets
};
let line_counts = line_offsets
.iter()
.map(|(line_start_offset, line_end_offset)| {
let mut count = 0;
// Count the hits of ranges that include the entire line which will always be at-least one
// as long as the code has been evaluated.
for function in &script_coverage.functions {
for range in &function.ranges {
if range.start_offset <= *line_start_offset
&& range.end_offset >= *line_end_offset
{
count += range.count;
}
}
}
// We reset the count if any block with a zero count overlaps with the line range.
for function in &script_coverage.functions {
for range in &function.ranges {
if range.count > 0 {
continue;
}
let overlaps = std::cmp::max(line_end_offset, &range.end_offset)
- std::cmp::min(line_start_offset, &range.start_offset)
< (line_end_offset - line_start_offset)
+ (range.end_offset - range.start_offset);
if overlaps {
count = 0;
}
}
}
count
})
.collect::<Vec<usize>>();
let found_lines = if let Some(source_map) = maybe_source_map.as_ref() {
let mut found_lines = line_counts
.iter()
.enumerate()
.map(|(index, count)| {
source_map
.tokens()
.filter(move |token| token.get_dst_line() as usize == index)
.map(move |token| (token.get_src_line() as usize, *count))
})
.flatten()
.collect::<Vec<(usize, usize)>>();
found_lines.sort_unstable_by_key(|(index, _)| *index);
found_lines.dedup_by_key(|(index, _)| *index);
found_lines
} else {
line_counts
.iter()
.enumerate()
.map(|(index, count)| (index, *count))
.collect::<Vec<(usize, usize)>>()
};
for (index, count) in &found_lines {
println!("DA:{},{}", index + 1, count);
}
let lines_hit = found_lines.iter().filter(|(_, count)| *count != 0).count();
println!("LH:{}", lines_hit);
let lines_found = found_lines.len();
println!("LF:{}", lines_found);
println!("end_of_record");
}
fn done(&mut self) {}
}
pub struct PrettyCoverageReporter {}
impl PrettyCoverageReporter {
pub fn new() -> PrettyCoverageReporter {
PrettyCoverageReporter {}
}
}
impl CoverageReporter for PrettyCoverageReporter {
fn visit_coverage(
&mut self,
script_coverage: &ScriptCoverage,
script_source: &str,
maybe_source_map: Option<Vec<u8>>,
maybe_original_source: Option<String>,
) {
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let maybe_source_map = maybe_source_map
.map(|source_map| SourceMap::from_slice(&source_map).unwrap());
let mut ignored_spans: Vec<Span> = Vec::new();
for item in ast::lex("", script_source, &MediaType::JavaScript) {
if let TokenOrComment::Token(_) = item.inner {
continue;
}
ignored_spans.push(item.span);
}
let lines = script_source.split('\n').collect::<Vec<_>>();
let line_offsets = {
let mut offsets: Vec<(usize, usize)> = Vec::new();
let mut index = 0;
for line in &lines {
offsets.push((index, index + line.len() + 1));
index += line.len() + 1;
}
offsets
};
// TODO(caspervonb): collect uncovered ranges on the lines so that we can highlight specific
// parts of a line in color (word diff style) instead of the entire line.
let line_counts = line_offsets
.iter()
.enumerate()
.map(|(index, (line_start_offset, line_end_offset))| {
let ignore = ignored_spans.iter().any(|span| {
(span.lo.0 as usize) <= *line_start_offset
&& (span.hi.0 as usize) >= *line_end_offset
});
if ignore {
return (index, 1);
}
let mut count = 0;
// Count the hits of ranges that include the entire line which will always be at-least one
// as long as the code has been evaluated.
for function in &script_coverage.functions {
for range in &function.ranges {
if range.start_offset <= *line_start_offset
&& range.end_offset >= *line_end_offset
{
count += range.count;
}
}
}
// We reset the count if any block with a zero count overlaps with the line range.
for function in &script_coverage.functions {
for range in &function.ranges {
if range.count > 0 {
continue;
}
let overlaps = std::cmp::max(line_end_offset, &range.end_offset)
- std::cmp::min(line_start_offset, &range.start_offset)
< (line_end_offset - line_start_offset)
+ (range.end_offset - range.start_offset);
if overlaps {
count = 0;
}
}
}
(index, count)
})
.collect::<Vec<(usize, usize)>>();
let lines = if let Some(original_source) = maybe_original_source.as_ref() {
original_source.split('\n').collect::<Vec<_>>()
} else {
lines
};
let line_counts = if let Some(source_map) = maybe_source_map.as_ref() {
let mut line_counts = line_counts
.iter()
.map(|(index, count)| {
source_map
.tokens()
.filter(move |token| token.get_dst_line() as usize == *index)
.map(move |token| (token.get_src_line() as usize, *count))
})
.flatten()
.collect::<Vec<(usize, usize)>>();
line_counts.sort_unstable_by_key(|(index, _)| *index);
line_counts.dedup_by_key(|(index, _)| *index);
line_counts
} else {
line_counts
};
print!("cover {} ... ", script_coverage.url);
let hit_lines = line_counts
.iter()
.filter(|(_, count)| *count != 0)
.map(|(index, _)| *index);
let missed_lines = line_counts
.iter()
.filter(|(_, count)| *count == 0)
.map(|(index, _)| *index);
let lines_found = line_counts.len();
let lines_hit = hit_lines.count();
let line_ratio = lines_hit as f32 / lines_found as f32;
let line_coverage =
format!("{:.3}% ({}/{})", line_ratio * 100.0, lines_hit, lines_found,);
if line_ratio >= 0.9 {
println!("{}", colors::green(&line_coverage));
} else if line_ratio >= 0.75 {
println!("{}", colors::yellow(&line_coverage));
} else {
println!("{}", colors::red(&line_coverage));
}
let mut last_line = None;
for line_index in missed_lines {
const WIDTH: usize = 4;
const SEPERATOR: &str = "|";
// Put a horizontal separator between disjoint runs of lines
if let Some(last_line) = last_line {
if last_line + 1 != line_index {
let dash = colors::gray("-".repeat(WIDTH + 1));
println!("{}{}{}", dash, colors::gray(SEPERATOR), dash);
}
}
println!(
"{:width$} {} {}",
line_index + 1,
colors::gray(SEPERATOR),
colors::red(&lines[line_index]),
width = WIDTH
);
last_line = Some(line_index);
}
}
fn done(&mut self) {}
}
fn collect_coverages(
files: Vec<PathBuf>,
ignore: Vec<PathBuf>,
) -> Result<Vec<ScriptCoverage>, AnyError> {
let mut coverages: Vec<ScriptCoverage> = Vec::new();
let file_paths = collect_files(&files, &ignore, |file_path| {
file_path.extension().map_or(false, |ext| ext == "json")
})?;
for file_path in file_paths {
let json = fs::read_to_string(file_path.as_path())?;
let new_coverage: ScriptCoverage = serde_json::from_str(&json)?;
let existing_coverage =
coverages.iter_mut().find(|x| x.url == new_coverage.url);
if let Some(existing_coverage) = existing_coverage {
for new_function in new_coverage.functions {
let existing_function = existing_coverage
.functions
.iter_mut()
.find(|x| x.function_name == new_function.function_name);
if let Some(existing_function) = existing_function {
for new_range in new_function.ranges {
let existing_range =
existing_function.ranges.iter_mut().find(|x| {
x.start_offset == new_range.start_offset
&& x.end_offset == new_range.end_offset
});
if let Some(existing_range) = existing_range {
existing_range.count += new_range.count;
} else {
existing_function.ranges.push(new_range);
}
}
} else {
existing_coverage.functions.push(new_function);
}
}
} else {
coverages.push(new_coverage);
}
}
coverages.sort_by_key(|k| k.url.clone());
Ok(coverages)
}
fn filter_coverages(
coverages: Vec<ScriptCoverage>,
include: Vec<String>,
exclude: Vec<String>,
) -> Vec<ScriptCoverage> {
let include: Vec<Regex> =
include.iter().map(|e| Regex::new(e).unwrap()).collect();
let exclude: Vec<Regex> =
exclude.iter().map(|e| Regex::new(e).unwrap()).collect();
coverages
.into_iter()
.filter(|e| {
let is_internal = e.url.starts_with("deno:")
|| e.url.ends_with("__anonymous__")
|| e.url.ends_with("$deno$test.ts");
let is_included = include.iter().any(|p| p.is_match(&e.url));
let is_excluded = exclude.iter().any(|p| p.is_match(&e.url));
(include.is_empty() || is_included) && !is_excluded && !is_internal
})
.collect::<Vec<ScriptCoverage>>()
}
pub async fn cover_files(
flags: Flags,
files: Vec<PathBuf>,
ignore: Vec<PathBuf>,
include: Vec<String>,
exclude: Vec<String>,
lcov: bool,
) -> Result<(), AnyError> {
let program_state = ProgramState::build(flags).await?;
let script_coverages = collect_coverages(files, ignore)?;
let script_coverages = filter_coverages(script_coverages, include, exclude);
let reporter_kind = if lcov {
CoverageReporterKind::Lcov
} else {
CoverageReporterKind::Pretty
};
let mut reporter = create_reporter(reporter_kind);
for script_coverage in script_coverages {
let module_specifier =
deno_core::resolve_url_or_path(&script_coverage.url)?;
program_state
.prepare_module_load(
module_specifier.clone(),
TypeLib::UnstableDenoWindow,
Permissions::allow_all(),
Permissions::allow_all(),
false,
program_state.maybe_import_map.clone(),
)
.await?;
let module_source = program_state.load(module_specifier.clone(), None)?;
let script_source = &module_source.code;
let maybe_source_map = program_state.get_source_map(&script_coverage.url);
let maybe_cached_source = program_state
.file_fetcher
.get_source(&module_specifier)
.map(|f| f.source);
reporter.visit_coverage(
&script_coverage,
&script_source,
maybe_source_map,
maybe_cached_source,
);
}
reporter.done();
Ok(())
}