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denoland-deno/cli/main.rs
Bartek Iwańczuk f83c756aa0
refactor: use a single Mutex in ProcState for module graph (#12489)
This commit factors out 4 different fields from "ProcState", that are behind
"Arc<Mutex<>>" into a single struct behind a single mutex.
2021-10-19 16:01:46 +02:00

1403 lines
39 KiB
Rust

// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license.
mod ast;
mod auth_tokens;
mod cache;
mod checksum;
mod compat;
mod config_file;
mod deno_dir;
mod diagnostics;
mod diff;
mod disk_cache;
mod emit;
mod errors;
mod file_fetcher;
mod file_watcher;
mod flags;
mod flags_allow_net;
mod fmt_errors;
mod fs_util;
mod http_cache;
mod http_util;
mod lockfile;
mod logger;
mod lsp;
mod module_loader;
mod ops;
mod proc_state;
mod resolver;
mod source_maps;
mod standalone;
mod text_encoding;
mod tokio_util;
mod tools;
mod tsc;
mod unix_util;
mod version;
use crate::file_fetcher::File;
use crate::file_watcher::ResolutionResult;
use crate::flags::BundleFlags;
use crate::flags::CacheFlags;
use crate::flags::CompileFlags;
use crate::flags::CompletionsFlags;
use crate::flags::CoverageFlags;
use crate::flags::DenoSubcommand;
use crate::flags::DocFlags;
use crate::flags::EvalFlags;
use crate::flags::Flags;
use crate::flags::FmtFlags;
use crate::flags::InfoFlags;
use crate::flags::InstallFlags;
use crate::flags::LintFlags;
use crate::flags::ReplFlags;
use crate::flags::RunFlags;
use crate::flags::TestFlags;
use crate::flags::UninstallFlags;
use crate::flags::UpgradeFlags;
use crate::fmt_errors::PrettyJsError;
use crate::module_loader::CliModuleLoader;
use crate::proc_state::ProcState;
use crate::resolver::ImportMapResolver;
use crate::source_maps::apply_source_map;
use crate::tools::installer::infer_name_from_url;
use deno_ast::MediaType;
use deno_core::error::generic_error;
use deno_core::error::AnyError;
use deno_core::futures::future::FutureExt;
use deno_core::futures::Future;
use deno_core::located_script_name;
use deno_core::resolve_url_or_path;
use deno_core::serde_json;
use deno_core::serde_json::json;
use deno_core::v8_set_flags;
use deno_core::JsRuntime;
use deno_core::ModuleSpecifier;
use deno_runtime::colors;
use deno_runtime::ops::worker_host::CreateWebWorkerCb;
use deno_runtime::permissions::Permissions;
use deno_runtime::web_worker::WebWorker;
use deno_runtime::web_worker::WebWorkerOptions;
use deno_runtime::worker::MainWorker;
use deno_runtime::worker::WorkerOptions;
use deno_runtime::BootstrapOptions;
use log::debug;
use log::info;
use std::env;
use std::io::Read;
use std::io::Write;
use std::iter::once;
use std::path::PathBuf;
use std::pin::Pin;
use std::rc::Rc;
use std::sync::Arc;
fn create_web_worker_callback(ps: ProcState) -> Arc<CreateWebWorkerCb> {
Arc::new(move |args| {
let global_state_ = ps.clone();
let js_error_create_fn = Rc::new(move |core_js_error| {
let source_mapped_error =
apply_source_map(&core_js_error, global_state_.clone());
PrettyJsError::create(source_mapped_error)
});
let maybe_inspector_server = ps.maybe_inspector_server.clone();
let module_loader = CliModuleLoader::new_for_worker(
ps.clone(),
args.parent_permissions.clone(),
);
let create_web_worker_cb = create_web_worker_callback(ps.clone());
let options = WebWorkerOptions {
bootstrap: BootstrapOptions {
args: ps.flags.argv.clone(),
apply_source_maps: true,
cpu_count: num_cpus::get(),
debug_flag: ps
.flags
.log_level
.map_or(false, |l| l == log::Level::Debug),
enable_testing_features: ps.flags.enable_testing_features,
location: Some(args.main_module.clone()),
no_color: !colors::use_color(),
runtime_version: version::deno(),
ts_version: version::TYPESCRIPT.to_string(),
unstable: ps.flags.unstable,
},
extensions: vec![],
unsafely_ignore_certificate_errors: ps
.flags
.unsafely_ignore_certificate_errors
.clone(),
root_cert_store: ps.root_cert_store.clone(),
user_agent: version::get_user_agent(),
seed: ps.flags.seed,
module_loader,
create_web_worker_cb,
js_error_create_fn: Some(js_error_create_fn),
use_deno_namespace: args.use_deno_namespace,
worker_type: args.worker_type,
maybe_inspector_server,
get_error_class_fn: Some(&crate::errors::get_error_class_name),
blob_store: ps.blob_store.clone(),
broadcast_channel: ps.broadcast_channel.clone(),
shared_array_buffer_store: Some(ps.shared_array_buffer_store.clone()),
compiled_wasm_module_store: Some(ps.compiled_wasm_module_store.clone()),
};
let bootstrap_options = options.bootstrap.clone();
// TODO(@AaronO): switch to bootstrap_from_options() once ops below are an extension
// since it uses sync_ops_cache() which currently depends on the Deno namespace
// which can be nuked when bootstrapping workers (use_deno_namespace: false)
let (mut worker, external_handle) = WebWorker::from_options(
args.name,
args.permissions,
args.main_module,
args.worker_id,
options,
);
// TODO(@AaronO): move to a JsRuntime Extension passed into options
// This block registers additional ops and state that
// are only available in the CLI
{
let js_runtime = &mut worker.js_runtime;
js_runtime
.op_state()
.borrow_mut()
.put::<ProcState>(ps.clone());
// Applies source maps - works in conjuction with `js_error_create_fn`
// above
ops::errors::init(js_runtime);
if args.use_deno_namespace {
ops::runtime_compiler::init(js_runtime);
}
js_runtime.sync_ops_cache();
}
worker.bootstrap(&bootstrap_options);
(worker, external_handle)
})
}
pub fn create_main_worker(
ps: &ProcState,
main_module: ModuleSpecifier,
permissions: Permissions,
maybe_op_init: Option<&dyn Fn(&mut JsRuntime)>,
) -> MainWorker {
let module_loader = CliModuleLoader::new(ps.clone());
let global_state_ = ps.clone();
let js_error_create_fn = Rc::new(move |core_js_error| {
let source_mapped_error =
apply_source_map(&core_js_error, global_state_.clone());
PrettyJsError::create(source_mapped_error)
});
let maybe_inspector_server = ps.maybe_inspector_server.clone();
let should_break_on_first_statement = ps.flags.inspect_brk.is_some();
let create_web_worker_cb = create_web_worker_callback(ps.clone());
let options = WorkerOptions {
bootstrap: BootstrapOptions {
apply_source_maps: true,
args: ps.flags.argv.clone(),
cpu_count: num_cpus::get(),
debug_flag: ps.flags.log_level.map_or(false, |l| l == log::Level::Debug),
enable_testing_features: ps.flags.enable_testing_features,
location: ps.flags.location.clone(),
no_color: !colors::use_color(),
runtime_version: version::deno(),
ts_version: version::TYPESCRIPT.to_string(),
unstable: ps.flags.unstable,
},
extensions: vec![],
unsafely_ignore_certificate_errors: ps
.flags
.unsafely_ignore_certificate_errors
.clone(),
root_cert_store: ps.root_cert_store.clone(),
user_agent: version::get_user_agent(),
seed: ps.flags.seed,
js_error_create_fn: Some(js_error_create_fn),
create_web_worker_cb,
maybe_inspector_server,
should_break_on_first_statement,
module_loader,
get_error_class_fn: Some(&crate::errors::get_error_class_name),
origin_storage_dir: ps.flags.location.clone().map(|loc| {
ps.dir
.root
.clone()
// TODO(@crowlKats): change to origin_data for 2.0
.join("location_data")
.join(checksum::gen(&[loc.to_string().as_bytes()]))
}),
blob_store: ps.blob_store.clone(),
broadcast_channel: ps.broadcast_channel.clone(),
shared_array_buffer_store: Some(ps.shared_array_buffer_store.clone()),
compiled_wasm_module_store: Some(ps.compiled_wasm_module_store.clone()),
};
let mut worker =
MainWorker::bootstrap_from_options(main_module, permissions, options);
// TODO(@AaronO): move to a JsRuntime Extension passed into options
// This block registers additional ops and state that
// are only available in the CLI
{
let js_runtime = &mut worker.js_runtime;
js_runtime
.op_state()
.borrow_mut()
.put::<ProcState>(ps.clone());
// Applies source maps - works in conjuction with `js_error_create_fn`
// above
ops::errors::init(js_runtime);
ops::runtime_compiler::init(js_runtime);
if let Some(op_init) = maybe_op_init {
op_init(js_runtime);
}
js_runtime.sync_ops_cache();
}
worker
}
pub fn write_to_stdout_ignore_sigpipe(
bytes: &[u8],
) -> Result<(), std::io::Error> {
use std::io::ErrorKind;
match std::io::stdout().write_all(bytes) {
Ok(()) => Ok(()),
Err(e) => match e.kind() {
ErrorKind::BrokenPipe => Ok(()),
_ => Err(e),
},
}
}
pub fn write_json_to_stdout<T>(value: &T) -> Result<(), AnyError>
where
T: ?Sized + serde::ser::Serialize,
{
let mut writer = std::io::BufWriter::new(std::io::stdout());
serde_json::to_writer_pretty(&mut writer, value)?;
writeln!(&mut writer)?;
Ok(())
}
fn print_cache_info(
state: &ProcState,
json: bool,
location: Option<&deno_core::url::Url>,
) -> Result<(), AnyError> {
let deno_dir = &state.dir.root;
let modules_cache = &state.file_fetcher.get_http_cache_location();
let typescript_cache = &state.dir.gen_cache.location;
let registry_cache =
&state.dir.root.join(lsp::language_server::REGISTRIES_PATH);
let mut origin_dir = state.dir.root.join("location_data");
if let Some(location) = &location {
origin_dir =
origin_dir.join(&checksum::gen(&[location.to_string().as_bytes()]));
}
if json {
let mut output = json!({
"denoDir": deno_dir,
"modulesCache": modules_cache,
"typescriptCache": typescript_cache,
"registryCache": registry_cache,
"originStorage": origin_dir,
});
if location.is_some() {
output["localStorage"] =
serde_json::to_value(origin_dir.join("local_storage"))?;
}
write_json_to_stdout(&output)
} else {
println!("{} {:?}", colors::bold("DENO_DIR location:"), deno_dir);
println!(
"{} {:?}",
colors::bold("Remote modules cache:"),
modules_cache
);
println!(
"{} {:?}",
colors::bold("Emitted modules cache:"),
typescript_cache
);
println!(
"{} {:?}",
colors::bold("Language server registries cache:"),
registry_cache,
);
println!("{} {:?}", colors::bold("Origin storage:"), origin_dir);
if location.is_some() {
println!(
"{} {:?}",
colors::bold("Local Storage:"),
origin_dir.join("local_storage"),
);
}
Ok(())
}
}
pub fn get_types(unstable: bool) -> String {
let mut types = vec![
crate::tsc::DENO_NS_LIB,
crate::tsc::DENO_CONSOLE_LIB,
crate::tsc::DENO_URL_LIB,
crate::tsc::DENO_WEB_LIB,
crate::tsc::DENO_FETCH_LIB,
crate::tsc::DENO_WEBGPU_LIB,
crate::tsc::DENO_WEBSOCKET_LIB,
crate::tsc::DENO_WEBSTORAGE_LIB,
crate::tsc::DENO_CRYPTO_LIB,
crate::tsc::DENO_BROADCAST_CHANNEL_LIB,
crate::tsc::DENO_NET_LIB,
crate::tsc::SHARED_GLOBALS_LIB,
crate::tsc::WINDOW_LIB,
];
if unstable {
types.push(crate::tsc::UNSTABLE_NS_LIB);
}
types.join("\n")
}
async fn compile_command(
flags: Flags,
compile_flags: CompileFlags,
) -> Result<(), AnyError> {
let debug = flags.log_level == Some(log::Level::Debug);
let run_flags = tools::standalone::compile_to_runtime_flags(
flags.clone(),
compile_flags.args,
)?;
let module_specifier = resolve_url_or_path(&compile_flags.source_file)?;
let ps = ProcState::build(flags.clone()).await?;
let deno_dir = &ps.dir;
let output = compile_flags.output.or_else(|| {
infer_name_from_url(&module_specifier).map(PathBuf::from)
}).ok_or_else(|| generic_error(
"An executable name was not provided. One could not be inferred from the URL. Aborting.",
))?;
let graph =
create_graph_and_maybe_check(module_specifier.clone(), &ps, debug).await?;
let (bundle_str, _) = bundle_module_graph(graph.as_ref(), &ps, &flags)?;
info!(
"{} {}",
colors::green("Compile"),
module_specifier.to_string()
);
// Select base binary based on target
let original_binary =
tools::standalone::get_base_binary(deno_dir, compile_flags.target.clone())
.await?;
let final_bin = tools::standalone::create_standalone_binary(
original_binary,
bundle_str,
run_flags,
)?;
info!("{} {}", colors::green("Emit"), output.display());
tools::standalone::write_standalone_binary(
output.clone(),
compile_flags.target,
final_bin,
)
.await?;
Ok(())
}
async fn info_command(
flags: Flags,
info_flags: InfoFlags,
) -> Result<(), AnyError> {
let ps = ProcState::build(flags).await?;
if let Some(specifier) = info_flags.file {
let specifier = resolve_url_or_path(&specifier)?;
let mut cache = cache::FetchCacher::new(
ps.dir.gen_cache.clone(),
ps.file_fetcher.clone(),
Permissions::allow_all(),
Permissions::allow_all(),
);
let maybe_locker = lockfile::as_maybe_locker(ps.lockfile.clone());
let maybe_resolver =
ps.maybe_import_map.as_ref().map(ImportMapResolver::new);
let graph = deno_graph::create_graph(
vec![specifier],
false,
None,
&mut cache,
maybe_resolver.as_ref().map(|r| r.as_resolver()),
maybe_locker,
None,
)
.await;
if info_flags.json {
write_json_to_stdout(&json!(graph))
} else {
write_to_stdout_ignore_sigpipe(graph.to_string().as_bytes())
.map_err(|err| err.into())
}
} else {
// If it was just "deno info" print location of caches and exit
print_cache_info(&ps, info_flags.json, ps.flags.location.as_ref())
}
}
async fn install_command(
flags: Flags,
install_flags: InstallFlags,
) -> Result<(), AnyError> {
let mut preload_flags = flags.clone();
preload_flags.inspect = None;
preload_flags.inspect_brk = None;
let permissions = Permissions::from_options(&preload_flags.clone().into());
let ps = ProcState::build(preload_flags).await?;
let main_module = resolve_url_or_path(&install_flags.module_url)?;
let mut worker =
create_main_worker(&ps, main_module.clone(), permissions, None);
// First, fetch and compile the module; this step ensures that the module exists.
worker.preload_module(&main_module, true).await?;
tools::installer::install(
flags,
&install_flags.module_url,
install_flags.args,
install_flags.name,
install_flags.root,
install_flags.force,
)
}
async fn uninstall_command(
uninstall_flags: UninstallFlags,
) -> Result<(), AnyError> {
tools::installer::uninstall(uninstall_flags.name, uninstall_flags.root)
}
async fn lsp_command() -> Result<(), AnyError> {
lsp::start().await
}
#[allow(clippy::too_many_arguments)]
async fn lint_command(
flags: Flags,
lint_flags: LintFlags,
) -> Result<(), AnyError> {
if lint_flags.rules {
tools::lint::print_rules_list(lint_flags.json);
return Ok(());
}
let ps = ProcState::build(flags.clone()).await?;
let maybe_lint_config = if let Some(config_file) = &ps.maybe_config_file {
config_file.to_lint_config()?
} else {
None
};
tools::lint::lint(maybe_lint_config, lint_flags, flags.watch).await
}
async fn cache_command(
flags: Flags,
cache_flags: CacheFlags,
) -> Result<(), AnyError> {
let lib = if flags.unstable {
emit::TypeLib::UnstableDenoWindow
} else {
emit::TypeLib::DenoWindow
};
let ps = ProcState::build(flags).await?;
for file in cache_flags.files {
let specifier = resolve_url_or_path(&file)?;
ps.prepare_module_load(
vec![specifier],
false,
lib.clone(),
Permissions::allow_all(),
Permissions::allow_all(),
)
.await?;
if let Some(graph_error) = ps.take_graph_error() {
return Err(graph_error.into());
}
}
Ok(())
}
async fn eval_command(
flags: Flags,
eval_flags: EvalFlags,
) -> Result<(), AnyError> {
// deno_graph works off of extensions for local files to determine the media
// type, and so our "fake" specifier needs to have the proper extension.
let main_module =
resolve_url_or_path(&format!("./$deno$eval.{}", eval_flags.ext)).unwrap();
let permissions = Permissions::from_options(&flags.clone().into());
let ps = ProcState::build(flags.clone()).await?;
let mut worker =
create_main_worker(&ps, main_module.clone(), permissions, None);
// Create a dummy source file.
let source_code = if eval_flags.print {
format!("console.log({})", eval_flags.code)
} else {
eval_flags.code
}
.into_bytes();
let file = File {
local: main_module.clone().to_file_path().unwrap(),
maybe_types: None,
media_type: MediaType::Unknown,
source: Arc::new(String::from_utf8(source_code)?),
specifier: main_module.clone(),
maybe_headers: None,
};
// Save our fake file into file fetcher cache
// to allow module access by TS compiler.
ps.file_fetcher.insert_cached(file);
debug!("main_module {}", &main_module);
if flags.compat {
worker.execute_side_module(&compat::GLOBAL_URL).await?;
}
worker.execute_main_module(&main_module).await?;
worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('load'))",
)?;
worker.run_event_loop(false).await?;
worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('unload'))",
)?;
Ok(())
}
async fn create_graph_and_maybe_check(
root: ModuleSpecifier,
ps: &ProcState,
debug: bool,
) -> Result<Arc<deno_graph::ModuleGraph>, AnyError> {
let mut cache = cache::FetchCacher::new(
ps.dir.gen_cache.clone(),
ps.file_fetcher.clone(),
Permissions::allow_all(),
Permissions::allow_all(),
);
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())
.flatten();
let maybe_resolver = ps.maybe_import_map.as_ref().map(ImportMapResolver::new);
let graph = Arc::new(
deno_graph::create_graph(
vec![root],
false,
maybe_imports,
&mut cache,
maybe_resolver.as_ref().map(|r| r.as_resolver()),
maybe_locker,
None,
)
.await,
);
// Ensure that all non-dynamic, non-type only imports are properly loaded and
// if not, error with the first issue encountered.
graph.valid().map_err(emit::GraphError::from)?;
// If there was a locker, validate the integrity of all the modules in the
// locker.
emit::lock(graph.as_ref());
if !ps.flags.no_check {
graph.valid_types_only().map_err(emit::GraphError::from)?;
let lib = if ps.flags.unstable {
emit::TypeLib::UnstableDenoWindow
} else {
emit::TypeLib::DenoWindow
};
let (ts_config, maybe_ignored_options) = emit::get_ts_config(
emit::ConfigType::Check {
tsc_emit: false,
lib,
},
ps.maybe_config_file.as_ref(),
None,
)?;
log::info!("{} {}", colors::green("Check"), graph.roots[0]);
if let Some(ignored_options) = maybe_ignored_options {
eprintln!("{}", ignored_options);
}
let maybe_config_specifier = ps
.maybe_config_file
.as_ref()
.map(|cf| ModuleSpecifier::from_file_path(&cf.path).unwrap());
let check_result = emit::check_and_maybe_emit(
graph.clone(),
&mut cache,
emit::CheckOptions {
debug,
emit_with_diagnostics: false,
maybe_config_specifier,
ts_config,
},
)?;
debug!("{}", check_result.stats);
if !check_result.diagnostics.is_empty() {
return Err(check_result.diagnostics.into());
}
}
Ok(graph)
}
fn bundle_module_graph(
graph: &deno_graph::ModuleGraph,
ps: &ProcState,
flags: &Flags,
) -> Result<(String, Option<String>), AnyError> {
info!("{} {}", colors::green("Bundle"), graph.roots[0]);
let (ts_config, maybe_ignored_options) = emit::get_ts_config(
emit::ConfigType::Bundle,
ps.maybe_config_file.as_ref(),
None,
)?;
if flags.no_check {
if let Some(ignored_options) = maybe_ignored_options {
eprintln!("{}", ignored_options);
}
}
emit::bundle(
graph,
emit::BundleOptions {
bundle_type: emit::BundleType::Module,
ts_config,
},
)
}
/// A function that converts a float to a string the represents a human
/// readable version of that number.
fn human_size(size: f64) -> String {
let negative = if size.is_sign_positive() { "" } else { "-" };
let size = size.abs();
let units = ["B", "KB", "MB", "GB", "TB", "PB", "EB", "ZB", "YB"];
if size < 1_f64 {
return format!("{}{}{}", negative, size, "B");
}
let delimiter = 1024_f64;
let exponent = std::cmp::min(
(size.ln() / delimiter.ln()).floor() as i32,
(units.len() - 1) as i32,
);
let pretty_bytes = format!("{:.2}", size / delimiter.powi(exponent))
.parse::<f64>()
.unwrap()
* 1_f64;
let unit = units[exponent as usize];
format!("{}{}{}", negative, pretty_bytes, unit)
}
async fn bundle_command(
flags: Flags,
bundle_flags: BundleFlags,
) -> Result<(), AnyError> {
let debug = flags.log_level == Some(log::Level::Debug);
let resolver = |_| {
let flags = flags.clone();
let source_file1 = bundle_flags.source_file.clone();
let source_file2 = bundle_flags.source_file.clone();
async move {
let module_specifier = resolve_url_or_path(&source_file1)?;
debug!(">>>>> bundle START");
let ps = ProcState::build(flags.clone()).await?;
let graph =
create_graph_and_maybe_check(module_specifier, &ps, debug).await?;
let mut paths_to_watch: Vec<PathBuf> = graph
.specifiers()
.iter()
.filter_map(|(_, r)| {
r.as_ref()
.ok()
.map(|(s, _)| s.to_file_path().ok())
.flatten()
})
.collect();
if let Some(import_map) = ps.flags.import_map_path.as_ref() {
paths_to_watch
.push(fs_util::resolve_from_cwd(std::path::Path::new(import_map))?);
}
Ok((paths_to_watch, graph, ps))
}
.map(move |result| match result {
Ok((paths_to_watch, graph, ps)) => ResolutionResult::Restart {
paths_to_watch,
result: Ok((ps, graph)),
},
Err(e) => ResolutionResult::Restart {
paths_to_watch: vec![PathBuf::from(source_file2)],
result: Err(e),
},
})
};
let operation = |(ps, graph): (ProcState, Arc<deno_graph::ModuleGraph>)| {
let flags = flags.clone();
let out_file = bundle_flags.out_file.clone();
async move {
let (bundle_emit, maybe_bundle_map) =
bundle_module_graph(graph.as_ref(), &ps, &flags)?;
debug!(">>>>> bundle END");
if let Some(out_file) = out_file.as_ref() {
let output_bytes = bundle_emit.as_bytes();
let output_len = output_bytes.len();
fs_util::write_file(out_file, output_bytes, 0o644)?;
info!(
"{} {:?} ({})",
colors::green("Emit"),
out_file,
colors::gray(human_size(output_len as f64))
);
if let Some(bundle_map) = maybe_bundle_map {
let map_bytes = bundle_map.as_bytes();
let map_len = map_bytes.len();
let ext = if let Some(curr_ext) = out_file.extension() {
format!("{}.map", curr_ext.to_string_lossy())
} else {
"map".to_string()
};
let map_out_file = out_file.with_extension(ext);
fs_util::write_file(&map_out_file, map_bytes, 0o644)?;
info!(
"{} {:?} ({})",
colors::green("Emit"),
map_out_file,
colors::gray(human_size(map_len as f64))
);
}
} else {
println!("{}", bundle_emit);
}
Ok(())
}
};
if flags.watch {
file_watcher::watch_func(resolver, operation, "Bundle").await?;
} else {
let module_graph =
if let ResolutionResult::Restart { result, .. } = resolver(None).await {
result?
} else {
unreachable!();
};
operation(module_graph).await?;
}
Ok(())
}
async fn doc_command(
flags: Flags,
doc_flags: DocFlags,
) -> Result<(), AnyError> {
tools::doc::print_docs(
flags,
doc_flags.source_file,
doc_flags.json,
doc_flags.filter,
doc_flags.private,
)
.await
}
async fn format_command(
flags: Flags,
fmt_flags: FmtFlags,
) -> Result<(), AnyError> {
let ps = ProcState::build(flags.clone()).await?;
let maybe_fmt_config = if let Some(config_file) = &ps.maybe_config_file {
config_file.to_fmt_config()?
} else {
None
};
if fmt_flags.files.len() == 1 && fmt_flags.files[0].to_string_lossy() == "-" {
return tools::fmt::format_stdin(
fmt_flags,
maybe_fmt_config.map(|c| c.options).unwrap_or_default(),
);
}
tools::fmt::format(fmt_flags, flags.watch, maybe_fmt_config).await?;
Ok(())
}
async fn run_repl(flags: Flags, repl_flags: ReplFlags) -> Result<(), AnyError> {
let main_module = resolve_url_or_path("./$deno$repl.ts").unwrap();
let permissions = Permissions::from_options(&flags.clone().into());
let ps = ProcState::build(flags.clone()).await?;
let mut worker =
create_main_worker(&ps, main_module.clone(), permissions, None);
if flags.compat {
worker.execute_side_module(&compat::GLOBAL_URL).await?;
}
worker.run_event_loop(false).await?;
tools::repl::run(&ps, worker, repl_flags.eval).await
}
async fn run_from_stdin(flags: Flags) -> Result<(), AnyError> {
let ps = ProcState::build(flags.clone()).await?;
let permissions = Permissions::from_options(&flags.clone().into());
let main_module = resolve_url_or_path("./$deno$stdin.ts").unwrap();
let mut worker =
create_main_worker(&ps.clone(), main_module.clone(), permissions, None);
let mut source = Vec::new();
std::io::stdin().read_to_end(&mut source)?;
// Create a dummy source file.
let source_file = File {
local: main_module.clone().to_file_path().unwrap(),
maybe_types: None,
media_type: MediaType::TypeScript,
source: Arc::new(String::from_utf8(source)?),
specifier: main_module.clone(),
maybe_headers: None,
};
// Save our fake file into file fetcher cache
// to allow module access by TS compiler
ps.file_fetcher.insert_cached(source_file);
debug!("main_module {}", main_module);
if flags.compat {
worker.execute_side_module(&compat::GLOBAL_URL).await?;
}
worker.execute_main_module(&main_module).await?;
worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('load'))",
)?;
worker.run_event_loop(false).await?;
worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('unload'))",
)?;
Ok(())
}
async fn run_with_watch(flags: Flags, script: String) -> Result<(), AnyError> {
let resolver = |_| {
let script1 = script.clone();
let script2 = script.clone();
let flags = flags.clone();
async move {
let main_module = resolve_url_or_path(&script1)?;
let ps = ProcState::build(flags).await?;
let mut cache = cache::FetchCacher::new(
ps.dir.gen_cache.clone(),
ps.file_fetcher.clone(),
Permissions::allow_all(),
Permissions::allow_all(),
);
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())
.flatten();
let maybe_resolver =
ps.maybe_import_map.as_ref().map(ImportMapResolver::new);
let graph = deno_graph::create_graph(
vec![main_module.clone()],
false,
maybe_imports,
&mut cache,
maybe_resolver.as_ref().map(|r| r.as_resolver()),
maybe_locker,
None,
)
.await;
graph.valid()?;
// Find all local files in graph
let mut paths_to_watch: Vec<PathBuf> = graph
.specifiers()
.iter()
.filter_map(|(_, r)| {
r.as_ref()
.ok()
.map(|(s, _)| s.to_file_path().ok())
.flatten()
})
.collect();
if let Some(import_map) = ps.flags.import_map_path.as_ref() {
paths_to_watch
.push(fs_util::resolve_from_cwd(std::path::Path::new(import_map))?);
}
Ok((paths_to_watch, main_module, ps))
}
.map(move |result| match result {
Ok((paths_to_watch, module_info, ps)) => ResolutionResult::Restart {
paths_to_watch,
result: Ok((ps, module_info)),
},
Err(e) => ResolutionResult::Restart {
paths_to_watch: vec![PathBuf::from(script2)],
result: Err(e),
},
})
};
/// The FileWatcherModuleExecutor provides module execution with safe dispatching of life-cycle events by tracking the
/// state of any pending events and emitting accordingly on drop in the case of a future
/// cancellation.
struct FileWatcherModuleExecutor {
worker: MainWorker,
pending_unload: bool,
compat: bool,
}
impl FileWatcherModuleExecutor {
pub fn new(worker: MainWorker, compat: bool) -> FileWatcherModuleExecutor {
FileWatcherModuleExecutor {
worker,
pending_unload: false,
compat,
}
}
/// Execute the given main module emitting load and unload events before and after execution
/// respectively.
pub async fn execute(
&mut self,
main_module: &ModuleSpecifier,
) -> Result<(), AnyError> {
if self.compat {
self.worker.execute_side_module(&compat::GLOBAL_URL).await?;
}
self.worker.execute_main_module(main_module).await?;
self.worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('load'))",
)?;
self.pending_unload = true;
let result = self.worker.run_event_loop(false).await;
self.pending_unload = false;
if let Err(err) = result {
return Err(err);
}
self.worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('unload'))",
)?;
Ok(())
}
}
impl Drop for FileWatcherModuleExecutor {
fn drop(&mut self) {
if self.pending_unload {
self
.worker
.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('unload'))",
)
.unwrap();
}
}
}
let operation = |(ps, main_module): (ProcState, ModuleSpecifier)| {
let flags = flags.clone();
let permissions = Permissions::from_options(&flags.clone().into());
async move {
// We make use an module executor guard to ensure that unload is always fired when an
// operation is called.
let mut executor = FileWatcherModuleExecutor::new(
create_main_worker(&ps, main_module.clone(), permissions, None),
flags.compat,
);
executor.execute(&main_module).await?;
Ok(())
}
};
file_watcher::watch_func(resolver, operation, "Process").await
}
async fn run_command(
flags: Flags,
run_flags: RunFlags,
) -> Result<(), AnyError> {
// Read script content from stdin
if run_flags.script == "-" {
return run_from_stdin(flags).await;
}
if flags.watch {
return run_with_watch(flags, run_flags.script).await;
}
// TODO(bartlomieju): it should not be resolved here if we're in compat mode
// because it might be a bare specifier
// TODO(bartlomieju): actually I think it will also fail if there's an import
// map specified and bare specifier is used on the command line - this should
// probably call `ProcState::resolve` instead
let main_module = resolve_url_or_path(&run_flags.script)?;
let ps = ProcState::build(flags.clone()).await?;
let permissions = Permissions::from_options(&flags.clone().into());
let mut worker =
create_main_worker(&ps, main_module.clone(), permissions, None);
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 =
tools::coverage::CoverageCollector::new(coverage_dir, session);
worker
.with_event_loop(coverage_collector.start_collecting().boxed_local())
.await?;
Some(coverage_collector)
} else {
None
};
debug!("main_module {}", main_module);
if flags.compat {
// TODO(bartlomieju): fix me
assert_eq!(main_module.scheme(), "file");
// Set up Node globals
worker.execute_side_module(&compat::GLOBAL_URL).await?;
// And `module` module that we'll use for checking which
// loader to use and potentially load CJS module with.
// This allows to skip permission check for `--allow-net`
// which would otherwise be requested by dynamically importing
// this file.
worker.execute_side_module(&compat::MODULE_URL).await?;
let use_esm_loader = compat::check_if_should_use_esm_loader(
&mut worker.js_runtime,
&main_module.to_file_path().unwrap().display().to_string(),
)
.await?;
if use_esm_loader {
// ES module execution in Node compatiblity mode
worker.execute_main_module(&main_module).await?;
} else {
// CJS module execution in Node compatiblity mode
compat::load_cjs_module(
&mut worker.js_runtime,
&main_module.to_file_path().unwrap().display().to_string(),
)?;
}
} else {
// Regular ES module execution
worker.execute_main_module(&main_module).await?;
}
worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('load'))",
)?;
worker
.run_event_loop(maybe_coverage_collector.is_none())
.await?;
worker.execute_script(
&located_script_name!(),
"window.dispatchEvent(new Event('unload'))",
)?;
if let Some(coverage_collector) = maybe_coverage_collector.as_mut() {
worker
.with_event_loop(coverage_collector.stop_collecting().boxed_local())
.await?;
}
Ok(())
}
async fn coverage_command(
flags: Flags,
coverage_flags: CoverageFlags,
) -> Result<(), AnyError> {
if coverage_flags.files.is_empty() {
return Err(generic_error("No matching coverage profiles found"));
}
tools::coverage::cover_files(
flags.clone(),
coverage_flags.files,
coverage_flags.ignore,
coverage_flags.include,
coverage_flags.exclude,
coverage_flags.lcov,
)
.await
}
async fn test_command(
flags: Flags,
test_flags: TestFlags,
) -> Result<(), AnyError> {
if let Some(ref coverage_dir) = flags.coverage_dir {
std::fs::create_dir_all(&coverage_dir)?;
env::set_var(
"DENO_UNSTABLE_COVERAGE_DIR",
PathBuf::from(coverage_dir).canonicalize()?,
);
}
if flags.watch {
tools::test::run_tests_with_watch(
flags,
test_flags.include,
test_flags.ignore,
test_flags.doc,
test_flags.no_run,
test_flags.fail_fast,
test_flags.filter,
test_flags.shuffle,
test_flags.concurrent_jobs,
)
.await?;
return Ok(());
}
tools::test::run_tests(
flags,
test_flags.include,
test_flags.ignore,
test_flags.doc,
test_flags.no_run,
test_flags.fail_fast,
test_flags.allow_none,
test_flags.filter,
test_flags.shuffle,
test_flags.concurrent_jobs,
)
.await?;
Ok(())
}
fn init_v8_flags(v8_flags: &[String]) {
let v8_flags_includes_help = v8_flags
.iter()
.any(|flag| flag == "-help" || flag == "--help");
// Keep in sync with `standalone.rs`.
let v8_flags = once("UNUSED_BUT_NECESSARY_ARG0".to_owned())
.chain(v8_flags.iter().cloned())
.collect::<Vec<_>>();
let unrecognized_v8_flags = v8_set_flags(v8_flags)
.into_iter()
.skip(1)
.collect::<Vec<_>>();
if !unrecognized_v8_flags.is_empty() {
for f in unrecognized_v8_flags {
eprintln!("error: V8 did not recognize flag '{}'", f);
}
eprintln!("\nFor a list of V8 flags, use '--v8-flags=--help'");
std::process::exit(1);
}
if v8_flags_includes_help {
std::process::exit(0);
}
}
fn get_subcommand(
flags: Flags,
) -> Pin<Box<dyn Future<Output = Result<(), AnyError>>>> {
match flags.clone().subcommand {
DenoSubcommand::Bundle(bundle_flags) => {
bundle_command(flags, bundle_flags).boxed_local()
}
DenoSubcommand::Doc(doc_flags) => {
doc_command(flags, doc_flags).boxed_local()
}
DenoSubcommand::Eval(eval_flags) => {
eval_command(flags, eval_flags).boxed_local()
}
DenoSubcommand::Cache(cache_flags) => {
cache_command(flags, cache_flags).boxed_local()
}
DenoSubcommand::Compile(compile_flags) => {
compile_command(flags, compile_flags).boxed_local()
}
DenoSubcommand::Coverage(coverage_flags) => {
coverage_command(flags, coverage_flags).boxed_local()
}
DenoSubcommand::Fmt(fmt_flags) => {
format_command(flags, fmt_flags).boxed_local()
}
DenoSubcommand::Info(info_flags) => {
info_command(flags, info_flags).boxed_local()
}
DenoSubcommand::Install(install_flags) => {
install_command(flags, install_flags).boxed_local()
}
DenoSubcommand::Uninstall(uninstall_flags) => {
uninstall_command(uninstall_flags).boxed_local()
}
DenoSubcommand::Lsp => lsp_command().boxed_local(),
DenoSubcommand::Lint(lint_flags) => {
lint_command(flags, lint_flags).boxed_local()
}
DenoSubcommand::Repl(repl_flags) => {
run_repl(flags, repl_flags).boxed_local()
}
DenoSubcommand::Run(run_flags) => {
run_command(flags, run_flags).boxed_local()
}
DenoSubcommand::Test(test_flags) => {
test_command(flags, test_flags).boxed_local()
}
DenoSubcommand::Completions(CompletionsFlags { buf }) => {
if let Err(e) = write_to_stdout_ignore_sigpipe(&buf) {
eprintln!("{}", e);
std::process::exit(1);
}
std::process::exit(0);
}
DenoSubcommand::Types => {
let types = get_types(flags.unstable);
if let Err(e) = write_to_stdout_ignore_sigpipe(types.as_bytes()) {
eprintln!("{}", e);
std::process::exit(1);
}
std::process::exit(0);
}
DenoSubcommand::Upgrade(upgrade_flags) => {
let UpgradeFlags {
force,
dry_run,
canary,
version,
output,
ca_file,
} = upgrade_flags;
tools::upgrade::upgrade_command(
dry_run, force, canary, version, output, ca_file,
)
.boxed_local()
}
}
}
fn setup_exit_process_panic_hook() {
// tokio does not exit the process when a task panics, so we
// define a custom panic hook to implement this behaviour
let orig_hook = std::panic::take_hook();
std::panic::set_hook(Box::new(move |panic_info| {
orig_hook(panic_info);
std::process::exit(1);
}));
}
fn unwrap_or_exit<T>(result: Result<T, AnyError>) -> T {
match result {
Ok(value) => value,
Err(error) => {
eprintln!("{}: {:?}", colors::red_bold("error"), error);
std::process::exit(1);
}
}
}
pub fn main() {
setup_exit_process_panic_hook();
#[cfg(windows)]
colors::enable_ansi(); // For Windows 10
unix_util::raise_fd_limit();
let args: Vec<String> = env::args().collect();
let standalone_res = match standalone::extract_standalone(args.clone()) {
Ok(Some((metadata, bundle))) => {
tokio_util::run_basic(standalone::run(bundle, metadata))
}
Ok(None) => Ok(()),
Err(err) => Err(err),
};
if let Err(err) = standalone_res {
eprintln!("{}: {}", colors::red_bold("error"), err.to_string());
std::process::exit(1);
}
let flags = match flags::flags_from_vec(args) {
Ok(flags) => flags,
Err(err @ clap::Error { .. })
if err.kind == clap::ErrorKind::HelpDisplayed
|| err.kind == clap::ErrorKind::VersionDisplayed =>
{
err.write_to(&mut std::io::stdout()).unwrap();
std::io::stdout().write_all(b"\n").unwrap();
std::process::exit(0);
}
Err(err) => unwrap_or_exit(Err(AnyError::from(err))),
};
if !flags.v8_flags.is_empty() {
init_v8_flags(&*flags.v8_flags);
}
logger::init(flags.log_level);
unwrap_or_exit(tokio_util::run_basic(get_subcommand(flags)));
}