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denoland-deno/cli/tools/test.rs

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// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license.
use crate::ast::Location;
use crate::colors;
use crate::create_main_worker;
use crate::file_fetcher::File;
use crate::file_watcher;
use crate::file_watcher::ResolutionResult;
use crate::flags::Flags;
use crate::fs_util::collect_specifiers;
use crate::fs_util::is_supported_test_ext;
use crate::fs_util::is_supported_test_path;
use crate::located_script_name;
use crate::module_graph;
use crate::module_graph::GraphBuilder;
use crate::module_graph::Module;
use crate::module_graph::TypeLib;
use crate::ops;
use crate::program_state::ProgramState;
use crate::tokio_util;
use crate::tools::coverage::CoverageCollector;
use crate::FetchHandler;
use deno_ast::swc::common::comments::CommentKind;
use deno_ast::MediaType;
use deno_core::error::generic_error;
use deno_core::error::AnyError;
use deno_core::futures::future;
use deno_core::futures::stream;
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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use deno_core::futures::FutureExt;
use deno_core::futures::StreamExt;
use deno_core::parking_lot::Mutex;
use deno_core::serde_json::json;
use deno_core::JsRuntime;
use deno_core::ModuleSpecifier;
use deno_runtime::permissions::Permissions;
use log::Level;
use rand::rngs::SmallRng;
use rand::seq::SliceRandom;
use rand::SeedableRng;
use regex::Regex;
use serde::Deserialize;
use std::collections::HashSet;
use std::num::NonZeroUsize;
use std::path::PathBuf;
use std::sync::mpsc::channel;
use std::sync::mpsc::Sender;
use std::sync::Arc;
use std::time::Duration;
use std::time::Instant;
use uuid::Uuid;
/// The test mode is used to determine how a specifier is to be tested.
#[derive(Debug, Clone, PartialEq)]
enum TestMode {
/// Test as documentation, type-checking fenced code blocks.
Documentation,
/// Test as an executable module, loading the module into the isolate and running each test it
/// defines.
Executable,
/// Test as both documentation and an executable module.
Both,
}
#[derive(Debug, Clone, PartialEq, Deserialize)]
#[serde(rename_all = "camelCase")]
pub struct TestDescription {
pub origin: String,
pub name: String,
}
#[derive(Debug, Clone, PartialEq, Deserialize)]
#[serde(rename_all = "camelCase")]
pub enum TestOutput {
// TODO(caspervonb): add stdout and stderr redirection.
Console(String),
}
#[derive(Debug, Clone, PartialEq, Deserialize)]
#[serde(rename_all = "camelCase")]
pub enum TestResult {
Ok,
Ignored,
Failed(String),
}
#[derive(Debug, Clone, PartialEq, Deserialize)]
#[serde(rename_all = "camelCase")]
pub struct TestPlan {
pub origin: String,
pub total: usize,
pub filtered_out: usize,
pub used_only: bool,
}
#[derive(Debug, Clone, Deserialize)]
#[serde(rename_all = "camelCase")]
pub enum TestEvent {
Plan(TestPlan),
Wait(TestDescription),
Output(TestOutput),
Result(TestDescription, TestResult, u64),
}
#[derive(Debug, Clone, Deserialize)]
pub struct TestSummary {
pub total: usize,
pub passed: usize,
pub failed: usize,
pub ignored: usize,
pub filtered_out: usize,
pub measured: usize,
pub failures: Vec<(TestDescription, String)>,
}
impl TestSummary {
fn new() -> TestSummary {
TestSummary {
total: 0,
passed: 0,
failed: 0,
ignored: 0,
filtered_out: 0,
measured: 0,
failures: Vec::new(),
}
}
fn has_failed(&self) -> bool {
self.failed > 0 || !self.failures.is_empty()
}
fn has_pending(&self) -> bool {
self.total - self.passed - self.failed - self.ignored > 0
}
}
trait TestReporter {
fn report_plan(&mut self, plan: &TestPlan);
fn report_wait(&mut self, description: &TestDescription);
fn report_output(&mut self, output: &TestOutput);
fn report_result(
&mut self,
description: &TestDescription,
result: &TestResult,
elapsed: u64,
);
fn report_summary(&mut self, summary: &TestSummary, elapsed: &Duration);
}
struct PrettyTestReporter {
concurrent: bool,
echo_output: bool,
}
impl PrettyTestReporter {
fn new(concurrent: bool, echo_output: bool) -> PrettyTestReporter {
PrettyTestReporter {
concurrent,
echo_output,
}
}
}
impl TestReporter for PrettyTestReporter {
fn report_plan(&mut self, plan: &TestPlan) {
let inflection = if plan.total == 1 { "test" } else { "tests" };
println!("running {} {} from {}", plan.total, inflection, plan.origin);
}
fn report_wait(&mut self, description: &TestDescription) {
if !self.concurrent {
print!("test {} ...", description.name);
}
}
fn report_output(&mut self, output: &TestOutput) {
if self.echo_output {
match output {
TestOutput::Console(line) => println!("{}", line),
}
}
}
fn report_result(
&mut self,
description: &TestDescription,
result: &TestResult,
elapsed: u64,
) {
if self.concurrent {
print!("test {} ...", description.name);
}
let status = match result {
TestResult::Ok => colors::green("ok").to_string(),
TestResult::Ignored => colors::yellow("ignored").to_string(),
TestResult::Failed(_) => colors::red("FAILED").to_string(),
};
println!(
" {} {}",
status,
colors::gray(format!("({}ms)", elapsed)).to_string()
);
}
fn report_summary(&mut self, summary: &TestSummary, elapsed: &Duration) {
if !summary.failures.is_empty() {
println!("\nfailures:\n");
for (description, error) in &summary.failures {
println!("{}", description.name);
println!("{}", error);
println!();
}
println!("failures:\n");
for (description, _) in &summary.failures {
println!("\t{}", description.name);
}
}
let status = if summary.has_failed() || summary.has_pending() {
colors::red("FAILED").to_string()
} else {
colors::green("ok").to_string()
};
println!(
"\ntest result: {}. {} passed; {} failed; {} ignored; {} measured; {} filtered out {}\n",
status,
summary.passed,
summary.failed,
summary.ignored,
summary.measured,
summary.filtered_out,
colors::gray(format!("({}ms)", elapsed.as_millis())),
);
}
}
fn create_reporter(
concurrent: bool,
echo_output: bool,
) -> Box<dyn TestReporter + Send> {
Box::new(PrettyTestReporter::new(concurrent, echo_output))
}
/// Test a single specifier as documentation containing test programs, an executable test module or
/// both.
async fn test_specifier(
program_state: Arc<ProgramState>,
permissions: Permissions,
specifier: ModuleSpecifier,
mode: TestMode,
filter: Option<String>,
shuffle: Option<u64>,
channel: Sender<TestEvent>,
) -> Result<(), AnyError> {
let test_specifier =
deno_core::resolve_path(&format!("{}$deno$test.js", Uuid::new_v4()))?;
let mut test_source = String::new();
if mode != TestMode::Documentation {
test_source.push_str(&format!("import \"{}\";\n", specifier));
}
let test_file = File {
local: test_specifier.to_file_path().unwrap(),
maybe_types: None,
media_type: MediaType::JavaScript,
source: Arc::new(test_source),
specifier: test_specifier.clone(),
maybe_headers: None,
};
program_state.file_fetcher.insert_cached(test_file);
let init_ops = |js_runtime: &mut JsRuntime| {
ops::testing::init(js_runtime);
js_runtime
.op_state()
.borrow_mut()
.put::<Sender<TestEvent>>(channel.clone());
};
let mut worker = create_main_worker(
&program_state,
specifier.clone(),
permissions,
Some(&init_ops),
);
let mut maybe_coverage_collector = if let Some(ref coverage_dir) =
program_state.coverage_dir
{
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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let session = worker.create_inspector_session().await;
let coverage_dir = PathBuf::from(coverage_dir);
let mut coverage_collector = CoverageCollector::new(coverage_dir, session);
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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worker
.with_event_loop(coverage_collector.start_collecting().boxed_local())
.await?;
Some(coverage_collector)
} else {
None
};
worker.execute_module(&test_specifier).await?;
worker.js_runtime.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('load'));",
)?;
let test_result = worker.js_runtime.execute_script(
&located_script_name!(),
&format!(
r#"Deno[Deno.internal].runTests({})"#,
json!({
"filter": filter,
"shuffle": shuffle,
}),
),
)?;
worker.js_runtime.resolve_value(test_result).await?;
worker.js_runtime.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('unload'));",
)?;
if let Some(coverage_collector) = maybe_coverage_collector.as_mut() {
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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worker
.with_event_loop(coverage_collector.stop_collecting().boxed_local())
.await?;
}
Ok(())
}
fn extract_files_from_regex_blocks(
location: &Location,
source: &str,
media_type: MediaType,
blocks_regex: &Regex,
lines_regex: &Regex,
) -> Result<Vec<File>, AnyError> {
let files = blocks_regex
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.captures_iter(source)
.filter_map(|block| {
let maybe_attributes: Option<Vec<_>> = block
.get(1)
.map(|attributes| attributes.as_str().split(' ').collect());
let file_media_type = if let Some(attributes) = maybe_attributes {
if attributes.contains(&"ignore") {
return None;
}
match attributes.get(0) {
Some(&"js") => MediaType::JavaScript,
Some(&"jsx") => MediaType::Jsx,
Some(&"ts") => MediaType::TypeScript,
Some(&"tsx") => MediaType::Tsx,
Some(&"") => media_type,
_ => MediaType::Unknown,
}
} else {
media_type
};
if file_media_type == MediaType::Unknown {
return None;
}
let line_offset = source[0..block.get(0).unwrap().start()]
.chars()
.filter(|c| *c == '\n')
.count();
let line_count = block.get(0).unwrap().as_str().split('\n').count();
let body = block.get(2).unwrap();
let text = body.as_str();
// TODO(caspervonb) generate an inline source map
let mut file_source = String::new();
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for line in lines_regex.captures_iter(text) {
let text = line.get(1).unwrap();
file_source.push_str(&format!("{}\n", text.as_str()));
}
file_source.push_str("export {};");
let file_specifier = deno_core::resolve_url_or_path(&format!(
"{}${}-{}{}",
location.specifier,
location.line + line_offset,
location.line + line_offset + line_count,
file_media_type.as_ts_extension(),
))
.unwrap();
Some(File {
local: file_specifier.to_file_path().unwrap(),
maybe_types: None,
media_type: file_media_type,
source: Arc::new(file_source),
specifier: file_specifier,
maybe_headers: None,
})
})
.collect();
Ok(files)
}
fn extract_files_from_source_comments(
specifier: &ModuleSpecifier,
source: Arc<String>,
media_type: MediaType,
) -> Result<Vec<File>, AnyError> {
let parsed_source = deno_ast::parse_module(deno_ast::ParseParams {
specifier: specifier.as_str().to_string(),
source: deno_ast::SourceTextInfo::new(
deno_ast::swc::common::BytePos(0),
source,
),
media_type,
capture_tokens: false,
maybe_syntax: None,
})?;
let comments = parsed_source.comments().get_vec();
let blocks_regex = Regex::new(r"```([^\n]*)\n([\S\s]*?)```")?;
let lines_regex = Regex::new(r"(?:\* ?)(?:\# ?)?(.*)")?;
let files = comments
.iter()
.filter(|comment| {
if comment.kind != CommentKind::Block || !comment.text.starts_with('*') {
return false;
}
true
})
.flat_map(|comment| {
let location = Location::from_pos(&parsed_source, comment.span.lo);
extract_files_from_regex_blocks(
&location,
&comment.text,
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media_type,
&blocks_regex,
&lines_regex,
)
})
.flatten()
.collect();
Ok(files)
}
fn extract_files_from_fenced_blocks(
specifier: &ModuleSpecifier,
source: &str,
media_type: MediaType,
) -> Result<Vec<File>, AnyError> {
let location = Location {
specifier: specifier.to_string(),
line: 1,
col: 0,
};
let blocks_regex = Regex::new(r"```([^\n]*)\n([\S\s]*?)```")?;
let lines_regex = Regex::new(r"(?:\# ?)?(.*)")?;
extract_files_from_regex_blocks(
&location,
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source,
media_type,
&blocks_regex,
&lines_regex,
)
}
async fn fetch_inline_files(
program_state: Arc<ProgramState>,
specifiers: Vec<ModuleSpecifier>,
) -> Result<Vec<File>, AnyError> {
let mut files = Vec::new();
for specifier in specifiers {
let mut fetch_permissions = Permissions::allow_all();
let file = program_state
.file_fetcher
.fetch(&specifier, &mut fetch_permissions)
.await?;
let inline_files = if file.media_type == MediaType::Unknown {
extract_files_from_fenced_blocks(
&file.specifier,
&file.source,
file.media_type,
)
} else {
extract_files_from_source_comments(
&file.specifier,
file.source.clone(),
file.media_type,
)
};
files.extend(inline_files?);
}
Ok(files)
}
/// Type check a collection of module and document specifiers.
async fn check_specifiers(
program_state: Arc<ProgramState>,
permissions: Permissions,
specifiers: Vec<(ModuleSpecifier, TestMode)>,
lib: TypeLib,
) -> Result<(), AnyError> {
let inline_files = fetch_inline_files(
program_state.clone(),
specifiers
.iter()
.filter_map(|(specifier, mode)| {
if *mode != TestMode::Executable {
Some(specifier.clone())
} else {
None
}
})
.collect(),
)
.await?;
if !inline_files.is_empty() {
let specifiers = inline_files
.iter()
.map(|file| file.specifier.clone())
.collect();
for file in inline_files {
program_state.file_fetcher.insert_cached(file);
}
program_state
.prepare_module_graph(
specifiers,
lib.clone(),
Permissions::allow_all(),
permissions.clone(),
program_state.maybe_import_map.clone(),
)
.await?;
}
let module_specifiers = specifiers
.iter()
.filter_map(|(specifier, mode)| {
if *mode != TestMode::Documentation {
Some(specifier.clone())
} else {
None
}
})
.collect();
program_state
.prepare_module_graph(
module_specifiers,
lib,
Permissions::allow_all(),
permissions,
program_state.maybe_import_map.clone(),
)
.await?;
Ok(())
}
/// Test a collection of specifiers with test modes concurrently.
async fn test_specifiers(
program_state: Arc<ProgramState>,
permissions: Permissions,
specifiers_with_mode: Vec<(ModuleSpecifier, TestMode)>,
fail_fast: Option<NonZeroUsize>,
filter: Option<String>,
shuffle: Option<u64>,
concurrent_jobs: NonZeroUsize,
) -> Result<(), AnyError> {
let log_level = program_state.flags.log_level;
let specifiers_with_mode = if let Some(seed) = shuffle {
let mut rng = SmallRng::seed_from_u64(seed);
let mut specifiers_with_mode = specifiers_with_mode.clone();
specifiers_with_mode.sort_by_key(|(specifier, _)| specifier.clone());
specifiers_with_mode.shuffle(&mut rng);
specifiers_with_mode
} else {
specifiers_with_mode
};
let (sender, receiver) = channel::<TestEvent>();
let join_handles =
specifiers_with_mode.iter().map(move |(specifier, mode)| {
let program_state = program_state.clone();
let permissions = permissions.clone();
let specifier = specifier.clone();
let mode = mode.clone();
let filter = filter.clone();
let sender = sender.clone();
tokio::task::spawn_blocking(move || {
let join_handle = std::thread::spawn(move || {
let future = test_specifier(
program_state,
permissions,
specifier,
mode,
filter,
shuffle,
sender,
);
tokio_util::run_basic(future)
});
join_handle.join().unwrap()
})
});
let join_stream = stream::iter(join_handles)
.buffer_unordered(concurrent_jobs.get())
.collect::<Vec<Result<Result<(), AnyError>, tokio::task::JoinError>>>();
let mut reporter =
create_reporter(concurrent_jobs.get() > 1, log_level != Some(Level::Error));
let handler = {
tokio::task::spawn_blocking(move || {
let earlier = Instant::now();
let mut summary = TestSummary::new();
let mut used_only = false;
for event in receiver.iter() {
match event {
TestEvent::Plan(plan) => {
summary.total += plan.total;
summary.filtered_out += plan.filtered_out;
if plan.used_only {
used_only = true;
}
reporter.report_plan(&plan);
}
TestEvent::Wait(description) => {
reporter.report_wait(&description);
}
TestEvent::Output(output) => {
reporter.report_output(&output);
}
TestEvent::Result(description, result, elapsed) => {
match &result {
TestResult::Ok => {
summary.passed += 1;
}
TestResult::Ignored => {
summary.ignored += 1;
}
TestResult::Failed(error) => {
summary.failed += 1;
summary.failures.push((description.clone(), error.clone()));
}
}
reporter.report_result(&description, &result, elapsed);
}
}
if let Some(x) = fail_fast {
if summary.failed >= x.get() {
break;
}
}
}
let elapsed = Instant::now().duration_since(earlier);
reporter.report_summary(&summary, &elapsed);
if used_only {
return Err(generic_error(
"Test failed because the \"only\" option was used",
));
}
if summary.failed > 0 {
return Err(generic_error("Test failed"));
}
Ok(())
})
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};
let (join_results, result) = future::join(join_stream, handler).await;
// propagate any errors
for join_result in join_results {
join_result??;
}
result??;
Ok(())
}
/// Collects specifiers marking them with the appropriate test mode while maintaining the natural
/// input order.
///
/// - Specifiers matching the `is_supported_test_ext` predicate are marked as
/// `TestMode::Documentation`.
/// - Specifiers matching the `is_supported_test_path` are marked as `TestMode::Executable`.
/// - Specifiers matching both predicates are marked as `TestMode::Both`
fn collect_specifiers_with_test_mode(
include: Vec<String>,
ignore: Vec<PathBuf>,
include_inline: bool,
) -> Result<Vec<(ModuleSpecifier, TestMode)>, AnyError> {
let module_specifiers =
collect_specifiers(include.clone(), &ignore, is_supported_test_path)?;
if include_inline {
return collect_specifiers(include, &ignore, is_supported_test_ext).map(
|specifiers| {
specifiers
.into_iter()
.map(|specifier| {
let mode = if module_specifiers.contains(&specifier) {
TestMode::Both
} else {
TestMode::Documentation
};
(specifier, mode)
})
.collect()
},
);
}
let specifiers_with_mode = module_specifiers
.into_iter()
.map(|specifier| (specifier, TestMode::Executable))
.collect();
Ok(specifiers_with_mode)
}
/// Collects module and document specifiers with test modes via `collect_specifiers_with_test_mode`
/// which are then pre-fetched and adjusted based on the media type.
///
/// Specifiers that do not have a known media type that can be executed as a module are marked as
/// `TestMode::Documentation`.
async fn fetch_specifiers_with_test_mode(
program_state: Arc<ProgramState>,
include: Vec<String>,
ignore: Vec<PathBuf>,
include_inline: bool,
) -> Result<Vec<(ModuleSpecifier, TestMode)>, AnyError> {
let mut specifiers_with_mode =
collect_specifiers_with_test_mode(include, ignore, include_inline)?;
for (specifier, mode) in &mut specifiers_with_mode {
let file = program_state
.file_fetcher
.fetch(specifier, &mut Permissions::allow_all())
.await?;
if file.media_type == MediaType::Unknown {
*mode = TestMode::Documentation
}
}
Ok(specifiers_with_mode)
}
#[allow(clippy::too_many_arguments)]
pub async fn run_tests(
flags: Flags,
include: Option<Vec<String>>,
ignore: Vec<PathBuf>,
doc: bool,
no_run: bool,
fail_fast: Option<NonZeroUsize>,
allow_none: bool,
filter: Option<String>,
shuffle: Option<u64>,
concurrent_jobs: NonZeroUsize,
) -> Result<(), AnyError> {
let program_state = ProgramState::build(flags.clone()).await?;
let permissions = Permissions::from_options(&flags.clone().into());
let specifiers_with_mode = fetch_specifiers_with_test_mode(
program_state.clone(),
include.unwrap_or_else(|| vec![".".to_string()]),
ignore.clone(),
doc,
)
.await?;
if !allow_none && specifiers_with_mode.is_empty() {
return Err(generic_error("No test modules found"));
}
let lib = if flags.unstable {
TypeLib::UnstableDenoWindow
} else {
TypeLib::DenoWindow
};
check_specifiers(
program_state.clone(),
permissions.clone(),
specifiers_with_mode.clone(),
lib,
)
.await?;
if no_run {
return Ok(());
}
test_specifiers(
program_state,
permissions,
specifiers_with_mode,
fail_fast,
filter,
shuffle,
concurrent_jobs,
)
.await?;
Ok(())
}
#[allow(clippy::too_many_arguments)]
pub async fn run_tests_with_watch(
flags: Flags,
include: Option<Vec<String>>,
ignore: Vec<PathBuf>,
doc: bool,
no_run: bool,
fail_fast: Option<NonZeroUsize>,
filter: Option<String>,
shuffle: Option<u64>,
concurrent_jobs: NonZeroUsize,
) -> Result<(), AnyError> {
let program_state = ProgramState::build(flags.clone()).await?;
let permissions = Permissions::from_options(&flags.clone().into());
let lib = if flags.unstable {
TypeLib::UnstableDenoWindow
} else {
TypeLib::DenoWindow
};
let handler = Arc::new(Mutex::new(FetchHandler::new(
&program_state,
Permissions::allow_all(),
Permissions::allow_all(),
)?));
let include = include.unwrap_or_else(|| vec![".".to_string()]);
let paths_to_watch: Vec<_> = include.iter().map(PathBuf::from).collect();
let resolver = |changed: Option<Vec<PathBuf>>| {
let paths_to_watch = paths_to_watch.clone();
let paths_to_watch_clone = paths_to_watch.clone();
let handler = handler.clone();
let program_state = program_state.clone();
let files_changed = changed.is_some();
let include = include.clone();
let ignore = ignore.clone();
async move {
let test_modules = if doc {
collect_specifiers(include.clone(), &ignore, is_supported_test_ext)
} else {
collect_specifiers(include.clone(), &ignore, is_supported_test_path)
}?;
let mut paths_to_watch = paths_to_watch_clone;
let mut modules_to_reload = if files_changed {
Vec::new()
} else {
test_modules
.iter()
.filter_map(|url| deno_core::resolve_url(url.as_str()).ok())
.collect()
};
let mut builder = GraphBuilder::new(
handler,
program_state.maybe_import_map.clone(),
program_state.lockfile.clone(),
);
for specifier in test_modules.iter() {
builder.add(specifier, false).await?;
}
builder
.analyze_config_file(&program_state.maybe_config_file)
.await?;
let graph = builder.get_graph();
for specifier in test_modules {
fn get_dependencies<'a>(
graph: &'a module_graph::Graph,
module: &'a Module,
// This needs to be accessible to skip getting dependencies if they're already there,
// otherwise this will cause a stack overflow with circular dependencies
output: &mut HashSet<&'a ModuleSpecifier>,
) -> Result<(), AnyError> {
for dep in module.dependencies.values() {
if let Some(specifier) = &dep.maybe_code {
if !output.contains(specifier) {
output.insert(specifier);
get_dependencies(
graph,
graph.get_specifier(specifier)?,
output,
)?;
}
}
if let Some(specifier) = &dep.maybe_type {
if !output.contains(specifier) {
output.insert(specifier);
get_dependencies(
graph,
graph.get_specifier(specifier)?,
output,
)?;
}
}
}
Ok(())
}
// This test module and all it's dependencies
let mut modules = HashSet::new();
modules.insert(&specifier);
get_dependencies(
&graph,
graph.get_specifier(&specifier)?,
&mut modules,
)?;
paths_to_watch.extend(
modules
.iter()
.filter_map(|specifier| specifier.to_file_path().ok()),
);
if let Some(changed) = &changed {
for path in changed.iter().filter_map(|path| {
deno_core::resolve_url_or_path(&path.to_string_lossy()).ok()
}) {
if modules.contains(&&path) {
modules_to_reload.push(specifier);
break;
}
}
}
}
Ok((paths_to_watch, modules_to_reload))
}
.map(move |result| {
if files_changed
&& matches!(result, Ok((_, ref modules)) if modules.is_empty())
{
ResolutionResult::Ignore
} else {
match result {
Ok((paths_to_watch, modules_to_reload)) => {
ResolutionResult::Restart {
paths_to_watch,
result: Ok(modules_to_reload),
}
}
Err(e) => ResolutionResult::Restart {
paths_to_watch,
result: Err(e),
},
}
}
})
};
let operation = |modules_to_reload: Vec<ModuleSpecifier>| {
let filter = filter.clone();
let include = include.clone();
let ignore = ignore.clone();
let lib = lib.clone();
let permissions = permissions.clone();
let program_state = program_state.clone();
async move {
let specifiers_with_mode = fetch_specifiers_with_test_mode(
program_state.clone(),
include.clone(),
ignore.clone(),
doc,
)
.await?
.iter()
.filter(|(specifier, _)| modules_to_reload.contains(specifier))
.cloned()
.collect::<Vec<(ModuleSpecifier, TestMode)>>();
check_specifiers(
program_state.clone(),
permissions.clone(),
specifiers_with_mode.clone(),
lib,
)
.await?;
if no_run {
return Ok(());
}
test_specifiers(
program_state.clone(),
permissions.clone(),
specifiers_with_mode,
fail_fast,
filter.clone(),
shuffle,
concurrent_jobs,
)
.await?;
Ok(())
}
};
file_watcher::watch_func(resolver, operation, "Test").await?;
Ok(())
}