deno/cli/lib.rs
2020-02-28 09:17:56 -05:00

491 lines
13 KiB
Rust

// Copyright 2018-2020 the Deno authors. All rights reserved. MIT license.
#![deny(warnings)]
#[macro_use]
extern crate lazy_static;
#[macro_use]
extern crate log;
extern crate futures;
#[macro_use]
extern crate serde_json;
extern crate clap;
extern crate deno_core;
extern crate indexmap;
#[cfg(unix)]
extern crate nix;
extern crate rand;
extern crate serde;
extern crate serde_derive;
extern crate tokio;
extern crate url;
mod checksum;
pub mod colors;
pub mod compilers;
pub mod deno_dir;
pub mod diagnostics;
mod disk_cache;
mod file_fetcher;
pub mod flags;
mod fmt;
pub mod fmt_errors;
mod fs;
mod global_state;
mod global_timer;
pub mod http_cache;
mod http_util;
mod import_map;
pub mod installer;
mod js;
mod lockfile;
mod metrics;
pub mod msg;
pub mod op_error;
pub mod ops;
pub mod permissions;
mod repl;
pub mod resolve_addr;
pub mod signal;
pub mod source_maps;
mod startup_data;
pub mod state;
mod test_runner;
pub mod test_util;
mod tokio_util;
pub mod version;
mod web_worker;
pub mod worker;
use crate::compilers::TargetLib;
use crate::file_fetcher::SourceFile;
use crate::fs as deno_fs;
use crate::global_state::GlobalState;
use crate::msg::MediaType;
use crate::ops::io::get_stdio;
use crate::state::State;
use crate::worker::MainWorker;
use deno_core::v8_set_flags;
use deno_core::ErrBox;
use deno_core::ModuleSpecifier;
use flags::DenoSubcommand;
use flags::Flags;
use futures::future::FutureExt;
use log::Level;
use log::Metadata;
use log::Record;
use std::env;
use std::fs as std_fs;
use std::io::Write;
use std::path::PathBuf;
use url::Url;
static LOGGER: Logger = Logger;
struct Logger;
impl log::Log for Logger {
fn enabled(&self, metadata: &Metadata) -> bool {
metadata.level() <= log::max_level()
}
fn log(&self, record: &Record) {
if self.enabled(record.metadata()) {
let mut target = record.target().to_string();
if let Some(line_no) = record.line() {
target.push_str(":");
target.push_str(&line_no.to_string());
}
println!("{} RS - {} - {}", record.level(), target, record.args());
}
}
fn flush(&self) {}
}
fn create_main_worker(
global_state: GlobalState,
main_module: ModuleSpecifier,
) -> Result<MainWorker, ErrBox> {
let state = State::new(global_state, None, main_module)?;
{
let mut s = state.borrow_mut();
let (stdin, stdout, stderr) = get_stdio();
s.resource_table.add("stdin", Box::new(stdin));
s.resource_table.add("stdout", Box::new(stdout));
s.resource_table.add("stderr", Box::new(stderr));
}
let mut worker = MainWorker::new(
"main".to_string(),
startup_data::deno_isolate_init(),
state,
);
worker.execute("bootstrapMainRuntime()")?;
Ok(worker)
}
fn print_cache_info(state: &GlobalState) {
println!(
"{} {:?}",
colors::bold("DENO_DIR location:".to_string()),
state.dir.root
);
println!(
"{} {:?}",
colors::bold("Remote modules cache:".to_string()),
state.file_fetcher.http_cache.location
);
println!(
"{} {:?}",
colors::bold("TypeScript compiler cache:".to_string()),
state.dir.gen_cache.location
);
}
// TODO(bartlomieju): this function de facto repeats
// whole compilation stack. Can this be done better somehow?
async fn print_file_info(
worker: &MainWorker,
module_specifier: ModuleSpecifier,
) -> Result<(), ErrBox> {
let global_state = worker.state.borrow().global_state.clone();
let out = global_state
.file_fetcher
.fetch_source_file(&module_specifier, None)
.await?;
println!(
"{} {}",
colors::bold("local:".to_string()),
out.filename.to_str().unwrap()
);
println!(
"{} {}",
colors::bold("type:".to_string()),
msg::enum_name_media_type(out.media_type)
);
let module_specifier_ = module_specifier.clone();
global_state
.clone()
.fetch_compiled_module(module_specifier_, None, TargetLib::Main)
.await?;
if out.media_type == msg::MediaType::TypeScript
|| (out.media_type == msg::MediaType::JavaScript
&& global_state.ts_compiler.compile_js)
{
let compiled_source_file = global_state
.ts_compiler
.get_compiled_source_file(&out.url)
.unwrap();
println!(
"{} {}",
colors::bold("compiled:".to_string()),
compiled_source_file.filename.to_str().unwrap(),
);
}
if let Ok(source_map) = global_state
.clone()
.ts_compiler
.get_source_map_file(&module_specifier)
{
println!(
"{} {}",
colors::bold("map:".to_string()),
source_map.filename.to_str().unwrap()
);
}
if let Some(deps) = worker.isolate.modules.deps(&module_specifier) {
println!("{}{}", colors::bold("deps:\n".to_string()), deps.name);
if let Some(ref depsdeps) = deps.deps {
for d in depsdeps {
println!("{}", d);
}
}
} else {
println!(
"{} cannot retrieve full dependency graph",
colors::bold("deps:".to_string()),
);
}
Ok(())
}
async fn info_command(
flags: Flags,
file: Option<String>,
) -> Result<(), ErrBox> {
let global_state = GlobalState::new(flags)?;
// If it was just "deno info" print location of caches and exit
if file.is_none() {
print_cache_info(&global_state);
return Ok(());
}
let main_module = ModuleSpecifier::resolve_url_or_path(&file.unwrap())?;
let mut worker = create_main_worker(global_state, main_module.clone())?;
worker.preload_module(&main_module).await?;
print_file_info(&worker, main_module.clone()).await
}
async fn install_command(
flags: Flags,
dir: Option<PathBuf>,
exe_name: String,
module_url: String,
args: Vec<String>,
force: bool,
) -> Result<(), ErrBox> {
// Firstly fetch and compile module, this step ensures that module exists.
let mut fetch_flags = flags.clone();
fetch_flags.reload = true;
let global_state = GlobalState::new(fetch_flags)?;
let main_module = ModuleSpecifier::resolve_url_or_path(&module_url)?;
let mut worker = create_main_worker(global_state, main_module.clone())?;
worker.preload_module(&main_module).await?;
installer::install(flags, dir, &exe_name, &module_url, args, force)
.map_err(ErrBox::from)
}
async fn fetch_command(flags: Flags, files: Vec<String>) -> Result<(), ErrBox> {
let main_module =
ModuleSpecifier::resolve_url_or_path("./__$deno$fetch.ts").unwrap();
let global_state = GlobalState::new(flags)?;
let mut worker =
create_main_worker(global_state.clone(), main_module.clone())?;
for file in files {
let specifier = ModuleSpecifier::resolve_url_or_path(&file)?;
worker.preload_module(&specifier).await.map(|_| ())?;
}
if global_state.flags.lock_write {
if let Some(ref lockfile) = global_state.lockfile {
let g = lockfile.lock().unwrap();
g.write()?;
} else {
eprintln!("--lock flag must be specified when using --lock-write");
std::process::exit(11);
}
}
Ok(())
}
async fn eval_command(
flags: Flags,
code: String,
as_typescript: bool,
) -> Result<(), ErrBox> {
// Force TypeScript compile.
let main_module =
ModuleSpecifier::resolve_url_or_path("./__$deno$eval.ts").unwrap();
let global_state = GlobalState::new(flags)?;
let mut worker = create_main_worker(global_state, main_module.clone())?;
let main_module_url = main_module.as_url().to_owned();
// Create a dummy source file.
let source_file = SourceFile {
filename: main_module_url.to_file_path().unwrap(),
url: main_module_url,
types_url: None,
media_type: if as_typescript {
MediaType::TypeScript
} else {
MediaType::JavaScript
},
source_code: code.clone().into_bytes(),
};
// Save our fake file into file fetcher cache
// to allow module access by TS compiler (e.g. op_fetch_source_files)
worker
.state
.borrow()
.global_state
.file_fetcher
.save_source_file_in_cache(&main_module, source_file);
debug!("main_module {}", &main_module);
worker.execute_module(&main_module).await?;
worker.execute("window.dispatchEvent(new Event('load'))")?;
(&mut *worker).await?;
worker.execute("window.dispatchEvent(new Event('unload'))")?;
Ok(())
}
async fn bundle_command(
flags: Flags,
source_file: String,
out_file: Option<PathBuf>,
) -> Result<(), ErrBox> {
let module_name = ModuleSpecifier::resolve_url_or_path(&source_file)?;
let global_state = GlobalState::new(flags)?;
debug!(">>>>> bundle START");
let bundle_result = global_state
.ts_compiler
.bundle(global_state.clone(), module_name.to_string(), out_file)
.await;
debug!(">>>>> bundle END");
bundle_result
}
async fn run_repl(flags: Flags) -> Result<(), ErrBox> {
let main_module =
ModuleSpecifier::resolve_url_or_path("./__$deno$repl.ts").unwrap();
let global_state = GlobalState::new(flags)?;
let mut worker = create_main_worker(global_state, main_module)?;
loop {
(&mut *worker).await?;
}
}
async fn run_command(flags: Flags, script: String) -> Result<(), ErrBox> {
let global_state = GlobalState::new(flags.clone())?;
let main_module = ModuleSpecifier::resolve_url_or_path(&script).unwrap();
let mut worker =
create_main_worker(global_state.clone(), main_module.clone())?;
debug!("main_module {}", main_module);
worker.execute_module(&main_module).await?;
worker.execute("window.dispatchEvent(new Event('load'))")?;
(&mut *worker).await?;
worker.execute("window.dispatchEvent(new Event('unload'))")?;
if global_state.flags.lock_write {
if let Some(ref lockfile) = global_state.lockfile {
let g = lockfile.lock().unwrap();
g.write()?;
} else {
eprintln!("--lock flag must be specified when using --lock-write");
std::process::exit(11);
}
}
Ok(())
}
async fn test_command(
flags: Flags,
include: Option<Vec<String>>,
fail_fast: bool,
_quiet: bool,
allow_none: bool,
) -> Result<(), ErrBox> {
let global_state = GlobalState::new(flags.clone())?;
let cwd = std::env::current_dir().expect("No current directory");
let include = include.unwrap_or_else(|| vec![".".to_string()]);
let test_modules = test_runner::prepare_test_modules_urls(include, &cwd)?;
if test_modules.is_empty() {
println!("No matching test modules found");
if !allow_none {
std::process::exit(1);
}
return Ok(());
}
let test_file = test_runner::render_test_file(test_modules, fail_fast);
let test_file_path = cwd.join(".deno.test.ts");
let test_file_url =
Url::from_file_path(&test_file_path).expect("Should be valid file url");
let main_module =
ModuleSpecifier::resolve_url(&test_file_url.to_string()).unwrap();
// First create worker with specified test file and only then write
// file to disk. Then test file will be executed and removed
// immediately after. That way even if compilation/tests fail test
// file can be cleaned up.
let mut worker =
create_main_worker(global_state.clone(), main_module.clone())?;
deno_fs::write_file(&test_file_path, test_file.as_bytes(), 0o666)
.expect("Can't write test file");
let execute_result = worker.execute_module(&main_module).await;
// Remove temporary test file
std_fs::remove_file(&test_file_path).expect("Failed to remove temp file");
execute_result?;
worker.execute("window.dispatchEvent(new Event('load'))")?;
(&mut *worker).await?;
worker.execute("window.dispatchEvent(new Event('unload'))")
}
pub fn main() {
#[cfg(windows)]
colors::enable_ansi(); // For Windows 10
log::set_logger(&LOGGER).unwrap();
let args: Vec<String> = env::args().collect();
let flags = flags::flags_from_vec(args);
if let Some(ref v8_flags) = flags.v8_flags {
let mut v8_flags_ = v8_flags.clone();
v8_flags_.insert(0, "UNUSED_BUT_NECESSARY_ARG0".to_string());
v8_set_flags(v8_flags_);
}
let log_level = match flags.log_level {
Some(level) => level,
None => Level::Warn,
};
log::set_max_level(log_level.to_level_filter());
let fut = match flags.clone().subcommand {
DenoSubcommand::Bundle {
source_file,
out_file,
} => bundle_command(flags, source_file, out_file).boxed_local(),
DenoSubcommand::Eval {
code,
as_typescript,
} => eval_command(flags, code, as_typescript).boxed_local(),
DenoSubcommand::Fetch { files } => {
fetch_command(flags, files).boxed_local()
}
DenoSubcommand::Fmt { check, files } => {
async move { fmt::format(files, check) }.boxed_local()
}
DenoSubcommand::Info { file } => info_command(flags, file).boxed_local(),
DenoSubcommand::Install {
dir,
exe_name,
module_url,
args,
force,
} => install_command(flags, dir, exe_name, module_url, args, force)
.boxed_local(),
DenoSubcommand::Repl => run_repl(flags).boxed_local(),
DenoSubcommand::Run { script } => run_command(flags, script).boxed_local(),
DenoSubcommand::Test {
quiet,
fail_fast,
include,
allow_none,
} => {
test_command(flags, include, fail_fast, quiet, allow_none).boxed_local()
}
DenoSubcommand::Completions { buf } => {
print!("{}", std::str::from_utf8(&buf).unwrap());
return;
}
DenoSubcommand::Types => {
let types = format!(
"{}\n{}\n{}",
crate::js::DENO_NS_LIB,
crate::js::SHARED_GLOBALS_LIB,
crate::js::WINDOW_LIB
);
// TODO(ry) Only ignore SIGPIPE. Currently ignoring all errors.
let _r = std::io::stdout().write_all(types.as_bytes());
return;
}
_ => unreachable!(),
};
let result = tokio_util::run_basic(fut);
if let Err(err) = result {
eprintln!("{}", err.to_string());
std::process::exit(1);
}
}