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denoland-deno/cli/tools/test.rs
2022-01-13 11:58:00 -05:00

1309 lines
34 KiB
Rust

// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.
use crate::cache;
use crate::cache::CacherLoader;
use crate::colors;
use crate::compat;
use crate::create_main_worker;
use crate::emit;
use crate::file_fetcher::File;
use crate::file_watcher;
use crate::file_watcher::ResolutionResult;
use crate::flags::CheckFlag;
use crate::flags::Flags;
use crate::flags::TestFlags;
use crate::fs_util::collect_specifiers;
use crate::fs_util::is_supported_test_ext;
use crate::fs_util::is_supported_test_path;
use crate::graph_util::graph_valid;
use crate::located_script_name;
use crate::lockfile;
use crate::ops;
use crate::proc_state::ProcState;
use crate::resolver::ImportMapResolver;
use crate::resolver::JsxResolver;
use crate::tools::coverage::CoverageCollector;
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;
use deno_core::futures::FutureExt;
use deno_core::futures::StreamExt;
use deno_core::serde_json::json;
use deno_core::ModuleSpecifier;
use deno_graph::Module;
use deno_runtime::permissions::Permissions;
use deno_runtime::tokio_util::run_basic;
use log::Level;
use rand::rngs::SmallRng;
use rand::seq::SliceRandom;
use rand::SeedableRng;
use regex::Regex;
use serde::Deserialize;
use std::collections::HashMap;
use std::collections::HashSet;
use std::io::Write;
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;
/// 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, Eq, Hash)]
#[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 TestStepDescription {
pub test: TestDescription,
pub level: usize,
pub name: String,
}
#[derive(Debug, Clone, PartialEq, Deserialize)]
#[serde(rename_all = "camelCase")]
pub enum TestStepResult {
Ok,
Ignored,
Failed(Option<String>),
Pending(Option<String>),
}
impl TestStepResult {
fn error(&self) -> Option<&str> {
match self {
TestStepResult::Failed(Some(text)) => Some(text.as_str()),
TestStepResult::Pending(Some(text)) => Some(text.as_str()),
_ => None,
}
}
}
#[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),
StepWait(TestStepDescription),
StepResult(TestStepDescription, TestStepResult, u64),
}
#[derive(Debug, Clone, Deserialize)]
pub struct TestSummary {
pub total: usize,
pub passed: usize,
pub failed: usize,
pub ignored: usize,
pub passed_steps: usize,
pub failed_steps: usize,
pub pending_steps: usize,
pub ignored_steps: usize,
pub filtered_out: usize,
pub measured: usize,
pub failures: Vec<(TestDescription, String)>,
}
#[derive(Debug, Clone, Deserialize)]
struct TestSpecifierOptions {
compat_mode: bool,
concurrent_jobs: NonZeroUsize,
fail_fast: Option<NonZeroUsize>,
filter: Option<String>,
shuffle: Option<u64>,
}
impl TestSummary {
fn new() -> TestSummary {
TestSummary {
total: 0,
passed: 0,
failed: 0,
ignored: 0,
passed_steps: 0,
failed_steps: 0,
pending_steps: 0,
ignored_steps: 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_step_wait(&mut self, description: &TestStepDescription);
fn report_step_result(
&mut self,
description: &TestStepDescription,
result: &TestStepResult,
elapsed: u64,
);
fn report_summary(&mut self, summary: &TestSummary, elapsed: &Duration);
}
enum DeferredStepOutput {
StepWait(TestStepDescription),
StepResult(TestStepDescription, TestStepResult, u64),
}
struct PrettyTestReporter {
concurrent: bool,
echo_output: bool,
deferred_step_output: HashMap<TestDescription, Vec<DeferredStepOutput>>,
last_wait_output_level: usize,
}
impl PrettyTestReporter {
fn new(concurrent: bool, echo_output: bool) -> PrettyTestReporter {
PrettyTestReporter {
concurrent,
echo_output,
deferred_step_output: HashMap::new(),
last_wait_output_level: 0,
}
}
fn force_report_wait(&mut self, description: &TestDescription) {
print!("test {} ...", description.name);
// flush for faster feedback when line buffered
std::io::stdout().flush().unwrap();
self.last_wait_output_level = 0;
}
fn force_report_step_wait(&mut self, description: &TestStepDescription) {
if self.last_wait_output_level < description.level {
println!();
}
print!(
"{}test {} ...",
" ".repeat(description.level),
description.name
);
// flush for faster feedback when line buffered
std::io::stdout().flush().unwrap();
self.last_wait_output_level = description.level;
}
fn force_report_step_result(
&mut self,
description: &TestStepDescription,
result: &TestStepResult,
elapsed: u64,
) {
let status = match result {
TestStepResult::Ok => colors::green("ok").to_string(),
TestStepResult::Ignored => colors::yellow("ignored").to_string(),
TestStepResult::Pending(_) => colors::gray("pending").to_string(),
TestStepResult::Failed(_) => colors::red("FAILED").to_string(),
};
if self.last_wait_output_level == description.level {
print!(" ");
} else {
print!("{}", " ".repeat(description.level));
}
println!(
"{} {}",
status,
colors::gray(human_elapsed(elapsed.into())).to_string()
);
if let Some(error_text) = result.error() {
for line in error_text.lines() {
println!("{}{}", " ".repeat(description.level + 1), line);
}
}
}
}
/// A function that converts a milisecond elapsed time to a string that
/// represents a human readable version of that time.
fn human_elapsed(elapsed: u128) -> String {
if elapsed < 1_000 {
return format!("({}ms)", elapsed);
}
if elapsed < 1_000 * 60 {
return format!("({}s)", elapsed / 1000);
}
let seconds = elapsed / 1_000;
let minutes = seconds / 60;
let seconds_remainder = seconds % 60;
format!("({}m{}s)", minutes, seconds_remainder)
}
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 {
self.force_report_wait(description);
}
}
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 {
self.force_report_wait(description);
if let Some(step_outputs) = self.deferred_step_output.remove(description)
{
for step_output in step_outputs {
match step_output {
DeferredStepOutput::StepWait(description) => {
self.force_report_step_wait(&description)
}
DeferredStepOutput::StepResult(
step_description,
step_result,
elapsed,
) => self.force_report_step_result(
&step_description,
&step_result,
elapsed,
),
}
}
}
}
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(),
};
if self.last_wait_output_level == 0 {
print!(" ");
}
println!(
"{} {}",
status,
colors::gray(human_elapsed(elapsed.into())).to_string()
);
}
fn report_step_wait(&mut self, description: &TestStepDescription) {
if self.concurrent {
self
.deferred_step_output
.entry(description.test.to_owned())
.or_insert_with(Vec::new)
.push(DeferredStepOutput::StepWait(description.clone()));
} else {
self.force_report_step_wait(description);
}
}
fn report_step_result(
&mut self,
description: &TestStepDescription,
result: &TestStepResult,
elapsed: u64,
) {
if self.concurrent {
self
.deferred_step_output
.entry(description.test.to_owned())
.or_insert_with(Vec::new)
.push(DeferredStepOutput::StepResult(
description.clone(),
result.clone(),
elapsed,
));
} else {
self.force_report_step_result(description, result, elapsed);
}
}
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()
};
let get_steps_text = |count: usize| -> String {
if count == 0 {
String::new()
} else if count == 1 {
" (1 step)".to_string()
} else {
format!(" ({} steps)", count)
}
};
println!(
"\ntest result: {}. {} passed{}; {} failed{}; {} ignored{}; {} measured; {} filtered out {}\n",
status,
summary.passed,
get_steps_text(summary.passed_steps),
summary.failed,
get_steps_text(summary.failed_steps + summary.pending_steps),
summary.ignored,
get_steps_text(summary.ignored_steps),
summary.measured,
summary.filtered_out,
colors::gray(human_elapsed(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(
ps: ProcState,
permissions: Permissions,
specifier: ModuleSpecifier,
mode: TestMode,
channel: Sender<TestEvent>,
options: TestSpecifierOptions,
) -> Result<(), AnyError> {
let mut worker = create_main_worker(
&ps,
specifier.clone(),
permissions,
vec![ops::testing::init(channel.clone())],
);
let mut maybe_coverage_collector = if let Some(ref coverage_dir) =
ps.coverage_dir
{
let session = worker.create_inspector_session().await;
let coverage_dir = PathBuf::from(coverage_dir);
let mut coverage_collector = CoverageCollector::new(coverage_dir, session);
worker
.with_event_loop(coverage_collector.start_collecting().boxed_local())
.await?;
Some(coverage_collector)
} else {
None
};
// We only execute the specifier as a module if it is tagged with TestMode::Module or
// TestMode::Both.
if mode != TestMode::Documentation {
if options.compat_mode {
worker.execute_side_module(&compat::GLOBAL_URL).await?;
worker.execute_side_module(&compat::MODULE_URL).await?;
let use_esm_loader = compat::check_if_should_use_esm_loader(&specifier)?;
if use_esm_loader {
worker.execute_side_module(&specifier).await?;
} else {
compat::load_cjs_module(
&mut worker.js_runtime,
&specifier.to_file_path().unwrap().display().to_string(),
false,
)?;
worker.run_event_loop(false).await?;
}
} else {
// We execute the module module as a side module so that import.meta.main is not set.
worker.execute_side_module(&specifier).await?;
}
}
worker.dispatch_load_event(&located_script_name!())?;
let test_result = worker.js_runtime.execute_script(
&located_script_name!(),
&format!(
r#"Deno[Deno.internal].runTests({})"#,
json!({
"filter": options.filter,
"shuffle": options.shuffle,
}),
),
)?;
worker.js_runtime.resolve_value(test_result).await?;
worker.dispatch_unload_event(&located_script_name!())?;
if let Some(coverage_collector) = maybe_coverage_collector.as_mut() {
worker
.with_event_loop(coverage_collector.stop_collecting().boxed_local())
.await?;
}
Ok(())
}
fn extract_files_from_regex_blocks(
specifier: &ModuleSpecifier,
source: &str,
media_type: MediaType,
file_line_index: usize,
blocks_regex: &Regex,
lines_regex: &Regex,
) -> Result<Vec<File>, AnyError> {
let files = blocks_regex
.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(&"mjs") => MediaType::Mjs,
Some(&"cjs") => MediaType::Cjs,
Some(&"jsx") => MediaType::Jsx,
Some(&"ts") => MediaType::TypeScript,
Some(&"mts") => MediaType::Mts,
Some(&"cts") => MediaType::Cts,
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();
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!(
"{}${}-{}{}",
specifier,
file_line_index + line_offset + 1,
file_line_index + line_offset + line_count + 1,
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(source),
media_type,
capture_tokens: false,
maybe_syntax: None,
scope_analysis: false,
})?;
let comments = parsed_source.comments().get_vec();
let blocks_regex = Regex::new(r"```([^\r\n]*)\r?\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| {
extract_files_from_regex_blocks(
specifier,
&comment.text,
media_type,
parsed_source.source().line_index(comment.span.lo),
&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 blocks_regex = Regex::new(r"```([^\r\n]*)\r?\n([\S\s]*?)```")?;
let lines_regex = Regex::new(r"(?:\# ?)?(.*)")?;
extract_files_from_regex_blocks(
specifier,
source,
media_type,
/* file line index */ 0,
&blocks_regex,
&lines_regex,
)
}
async fn fetch_inline_files(
ps: ProcState,
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 = ps
.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(
ps: ProcState,
permissions: Permissions,
specifiers: Vec<(ModuleSpecifier, TestMode)>,
lib: emit::TypeLib,
) -> Result<(), AnyError> {
let inline_files = fetch_inline_files(
ps.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 {
ps.file_fetcher.insert_cached(file);
}
ps.prepare_module_load(
specifiers,
false,
lib.clone(),
Permissions::allow_all(),
permissions.clone(),
false,
)
.await?;
}
let module_specifiers = specifiers
.iter()
.filter_map(|(specifier, mode)| {
if *mode != TestMode::Documentation {
Some(specifier.clone())
} else {
None
}
})
.collect();
ps.prepare_module_load(
module_specifiers,
false,
lib,
Permissions::allow_all(),
permissions,
true,
)
.await?;
Ok(())
}
/// Test a collection of specifiers with test modes concurrently.
async fn test_specifiers(
ps: ProcState,
permissions: Permissions,
specifiers_with_mode: Vec<(ModuleSpecifier, TestMode)>,
options: TestSpecifierOptions,
) -> Result<(), AnyError> {
let log_level = ps.flags.log_level;
let specifiers_with_mode = if let Some(seed) = options.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 concurrent_jobs = options.concurrent_jobs;
let fail_fast = options.fail_fast;
let join_handles =
specifiers_with_mode.iter().map(move |(specifier, mode)| {
let ps = ps.clone();
let permissions = permissions.clone();
let specifier = specifier.clone();
let mode = mode.clone();
let sender = sender.clone();
let options = options.clone();
tokio::task::spawn_blocking(move || {
let join_handle = std::thread::spawn(move || {
let future =
test_specifier(ps, permissions, specifier, mode, sender, options);
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);
}
TestEvent::StepWait(description) => {
reporter.report_step_wait(&description);
}
TestEvent::StepResult(description, result, duration) => {
match &result {
TestStepResult::Ok => {
summary.passed_steps += 1;
}
TestStepResult::Ignored => {
summary.ignored_steps += 1;
}
TestStepResult::Failed(_) => {
summary.failed_steps += 1;
}
TestStepResult::Pending(_) => {
summary.pending_steps += 1;
}
}
reporter.report_step_result(&description, &result, duration);
}
}
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(())
})
};
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`. Type definition files
/// cannot be run, and therefore need to be marked as `TestMode::Documentation`
/// as well.
async fn fetch_specifiers_with_test_mode(
ps: ProcState,
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 = ps
.file_fetcher
.fetch(specifier, &mut Permissions::allow_all())
.await?;
if file.media_type == MediaType::Unknown
|| file.media_type == MediaType::Dts
{
*mode = TestMode::Documentation
}
}
Ok(specifiers_with_mode)
}
pub async fn run_tests(
flags: Flags,
test_flags: TestFlags,
) -> Result<(), AnyError> {
let ps = ProcState::build(flags.clone()).await?;
let permissions = Permissions::from_options(&flags.clone().into());
let specifiers_with_mode = fetch_specifiers_with_test_mode(
ps.clone(),
test_flags.include.unwrap_or_else(|| vec![".".to_string()]),
test_flags.ignore.clone(),
test_flags.doc,
)
.await?;
if !test_flags.allow_none && specifiers_with_mode.is_empty() {
return Err(generic_error("No test modules found"));
}
let lib = if flags.unstable {
emit::TypeLib::UnstableDenoWindow
} else {
emit::TypeLib::DenoWindow
};
check_specifiers(
ps.clone(),
permissions.clone(),
specifiers_with_mode.clone(),
lib,
)
.await?;
if test_flags.no_run {
return Ok(());
}
test_specifiers(
ps,
permissions,
specifiers_with_mode,
TestSpecifierOptions {
compat_mode: flags.compat,
concurrent_jobs: test_flags.concurrent_jobs,
fail_fast: test_flags.fail_fast,
filter: test_flags.filter,
shuffle: test_flags.shuffle,
},
)
.await?;
Ok(())
}
pub async fn run_tests_with_watch(
flags: Flags,
test_flags: TestFlags,
) -> Result<(), AnyError> {
let ps = ProcState::build(flags.clone()).await?;
let permissions = Permissions::from_options(&flags.clone().into());
let lib = if flags.unstable {
emit::TypeLib::UnstableDenoWindow
} else {
emit::TypeLib::DenoWindow
};
let include = test_flags.include.unwrap_or_else(|| vec![".".to_string()]);
let ignore = test_flags.ignore.clone();
let paths_to_watch: Vec<_> = include.iter().map(PathBuf::from).collect();
let no_check = ps.flags.check == CheckFlag::None;
let resolver = |changed: Option<Vec<PathBuf>>| {
let mut cache = cache::FetchCacher::new(
ps.dir.gen_cache.clone(),
ps.file_fetcher.clone(),
Permissions::allow_all(),
Permissions::allow_all(),
);
let paths_to_watch = paths_to_watch.clone();
let paths_to_watch_clone = paths_to_watch.clone();
let maybe_import_map_resolver =
ps.maybe_import_map.clone().map(ImportMapResolver::new);
let maybe_jsx_resolver = ps
.maybe_config_file
.as_ref()
.map(|cf| {
cf.to_maybe_jsx_import_source_module()
.map(|im| JsxResolver::new(im, maybe_import_map_resolver.clone()))
})
.flatten();
let maybe_locker = lockfile::as_maybe_locker(ps.lockfile.clone());
let maybe_imports = ps
.maybe_config_file
.as_ref()
.map(|cf| cf.to_maybe_imports());
let files_changed = changed.is_some();
let include = include.clone();
let ignore = ignore.clone();
let check_js = ps
.maybe_config_file
.as_ref()
.map(|cf| cf.get_check_js())
.unwrap_or(false);
async move {
let test_modules = if test_flags.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 maybe_imports = if let Some(result) = maybe_imports {
result?
} else {
None
};
let maybe_resolver = if maybe_jsx_resolver.is_some() {
maybe_jsx_resolver.as_ref().map(|jr| jr.as_resolver())
} else {
maybe_import_map_resolver
.as_ref()
.map(|im| im.as_resolver())
};
let graph = deno_graph::create_graph(
test_modules.clone(),
false,
maybe_imports,
cache.as_mut_loader(),
maybe_resolver,
maybe_locker,
None,
None,
)
.await;
graph_valid(&graph, !no_check, check_js)?;
// TODO(@kitsonk) - This should be totally derivable from the graph.
for specifier in test_modules {
fn get_dependencies<'a>(
graph: &'a deno_graph::ModuleGraph,
maybe_module: Option<&'a deno_graph::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>,
no_check: bool,
) {
if let Some(Module::Es(module)) = maybe_module {
for dep in module.dependencies.values() {
if let Some(specifier) = &dep.get_code() {
if !output.contains(specifier) {
output.insert(specifier);
get_dependencies(
graph,
graph.get(specifier),
output,
no_check,
);
}
}
if !no_check {
if let Some(specifier) = &dep.get_type() {
if !output.contains(specifier) {
output.insert(specifier);
get_dependencies(
graph,
graph.get(specifier),
output,
no_check,
);
}
}
}
}
}
}
// This test module and all it's dependencies
let mut modules = HashSet::new();
modules.insert(&specifier);
get_dependencies(&graph, graph.get(&specifier), &mut modules, no_check);
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 = test_flags.filter.clone();
let include = include.clone();
let ignore = ignore.clone();
let lib = lib.clone();
let permissions = permissions.clone();
let ps = ps.clone();
async move {
let specifiers_with_mode = fetch_specifiers_with_test_mode(
ps.clone(),
include.clone(),
ignore.clone(),
test_flags.doc,
)
.await?
.iter()
.filter(|(specifier, _)| modules_to_reload.contains(specifier))
.cloned()
.collect::<Vec<(ModuleSpecifier, TestMode)>>();
check_specifiers(
ps.clone(),
permissions.clone(),
specifiers_with_mode.clone(),
lib,
)
.await?;
if test_flags.no_run {
return Ok(());
}
test_specifiers(
ps.clone(),
permissions.clone(),
specifiers_with_mode,
TestSpecifierOptions {
compat_mode: flags.compat,
concurrent_jobs: test_flags.concurrent_jobs,
fail_fast: test_flags.fail_fast,
filter: filter.clone(),
shuffle: test_flags.shuffle,
},
)
.await?;
Ok(())
}
};
file_watcher::watch_func(resolver, operation, "Test").await?;
Ok(())
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_human_elapsed() {
assert_eq!(human_elapsed(1), "(1ms)");
assert_eq!(human_elapsed(256), "(256ms)");
assert_eq!(human_elapsed(1000), "(1s)");
assert_eq!(human_elapsed(1001), "(1s)");
assert_eq!(human_elapsed(1020), "(1s)");
assert_eq!(human_elapsed(70 * 1000), "(1m10s)");
assert_eq!(human_elapsed(86 * 1000 + 100), "(1m26s)");
}
}