// 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 deno_error; 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; mod http_util; mod import_map; pub mod installer; mod js; mod lockfile; mod metrics; pub mod msg; pub mod ops; pub mod permissions; mod progress; mod repl; pub mod resolve_addr; mod shell; pub mod signal; pub mod source_maps; mod startup_data; pub mod state; pub mod test_util; mod tokio_util; pub mod version; mod web_worker; pub mod worker; use crate::compilers::TargetLib; use crate::deno_error::js_check; use crate::deno_error::{print_err_and_exit, print_msg_and_exit}; use crate::global_state::ThreadSafeGlobalState; use crate::ops::io::get_stdio; use crate::progress::Progress; use crate::state::ThreadSafeState; use crate::worker::MainWorker; use deno_core::v8_set_flags; use deno_core::ErrBox; use deno_core::ModuleSpecifier; use flags::DenoFlags; use flags::DenoSubcommand; use log::Level; use log::Metadata; use log::Record; use std::env; 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_worker_and_state( flags: DenoFlags, ) -> (MainWorker, ThreadSafeGlobalState) { use crate::shell::Shell; use std::sync::Arc; use std::sync::Mutex; let shell = Arc::new(Mutex::new(Shell::new())); let progress = Progress::new(); progress.set_callback(move |_done, _completed, _total, status, msg| { if !status.is_empty() { let mut s = shell.lock().unwrap(); s.status(status, msg).expect("shell problem"); } }); let global_state = ThreadSafeGlobalState::new(flags, progress) .map_err(deno_error::print_err_and_exit) .unwrap(); let (int, ext) = ThreadSafeState::create_channels(); let state = ThreadSafeState::new( global_state.clone(), None, global_state.main_module.clone(), int, ) .map_err(deno_error::print_err_and_exit) .unwrap(); let state_ = state.clone(); { let mut resource_table = state_.lock_resource_table(); let (stdin, stdout, stderr) = get_stdio(); resource_table.add("stdin", Box::new(stdin)); resource_table.add("stdout", Box::new(stdout)); resource_table.add("stderr", Box::new(stderr)); } let worker = MainWorker::new( "main".to_string(), startup_data::deno_isolate_init(), state, ext, ); (worker, global_state) } fn types_command() { println!( "{}\n{}\n{}", crate::js::DENO_NS_LIB, crate::js::SHARED_GLOBALS_LIB, crate::js::WINDOW_LIB ); } fn print_cache_info(worker: MainWorker) { let state = &worker.state.global_state; println!( "{} {:?}", colors::bold("DENO_DIR location:".to_string()), state.dir.root ); println!( "{} {:?}", colors::bold("Remote modules cache:".to_string()), state.dir.deps_cache.location ); println!( "{} {:?}", colors::bold("TypeScript compiler cache:".to_string()), state.dir.gen_cache.location ); } async fn print_file_info( worker: MainWorker, module_specifier: ModuleSpecifier, ) { let global_state_ = &worker.state.global_state; let maybe_source_file = global_state_ .file_fetcher .fetch_source_file_async(&module_specifier, None) .await; if let Err(err) = maybe_source_file { println!("{}", err); return; } let out = maybe_source_file.unwrap(); 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 maybe_compiled = global_state_ .clone() .fetch_compiled_module(&module_specifier, None, TargetLib::Main) .await; if let Err(e) = maybe_compiled { debug!("compiler error exiting!"); eprintln!("\n{}", e.to_string()); std::process::exit(1); } 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() ); } let isolate = worker.isolate.try_lock().unwrap(); if let Some(deps) = 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()), ); } } async fn info_command(flags: DenoFlags) { let argv_len = flags.argv.len(); let (mut worker, state) = create_worker_and_state(flags); // If it was just "deno info" print location of caches and exit if argv_len == 1 { return print_cache_info(worker); } let main_module = state.main_module.as_ref().unwrap().clone(); // Setup runtime. js_check(worker.execute("bootstrapMainRuntime()")); debug!("main_module {}", main_module); let main_result = worker.execute_mod_async(&main_module, None, true).await; if let Err(e) = main_result { print_err_and_exit(e); } print_file_info(worker.clone(), main_module.clone()).await; let result = worker.await; js_check(result); } async fn install_command( flags: DenoFlags, dir: Option, exe_name: String, module_url: String, args: Vec, ) { // Firstly fetch and compile module, this // ensures the module exists. let mut fetch_flags = flags.clone(); fetch_flags.argv.push(module_url.to_string()); fetch_flags.reload = true; fetch_command(fetch_flags).await; let install_result = installer::install(flags, dir, &exe_name, &module_url, args); if let Err(e) = install_result { print_msg_and_exit(&e.to_string()); } } async fn fetch_command(flags: DenoFlags) { let args = flags.argv.clone(); let (mut worker, state) = create_worker_and_state(flags); let main_module = state.main_module.as_ref().unwrap().clone(); // Setup runtime. js_check(worker.execute("bootstrapMainRuntime()")); debug!("main_module {}", main_module); let result = worker.execute_mod_async(&main_module, None, true).await; js_check(result); // resolve modules for rest of args if present let files_len = args.len(); if files_len > 2 { for next_specifier in args.iter().take(files_len).skip(2) { let next_module = ModuleSpecifier::resolve_url_or_path(&next_specifier).unwrap(); let result = worker.execute_mod_async(&next_module, None, true).await; js_check(result); } } if state.flags.lock_write { if let Some(ref lockfile) = state.lockfile { let g = lockfile.lock().unwrap(); if let Err(e) = g.write() { print_err_and_exit(ErrBox::from(e)); } } else { eprintln!("--lock flag must be specified when using --lock-write"); std::process::exit(11); } } } async fn eval_command(flags: DenoFlags) { let ts_source = flags.argv[1].clone(); let (mut worker, _state) = create_worker_and_state(flags); // Force TypeScript compile. let main_module = ModuleSpecifier::resolve_url_or_path("./__$deno$eval.ts").unwrap(); js_check(worker.execute("bootstrapMainRuntime()")); debug!("main_module {}", &main_module); let exec_result = worker .execute_mod_async(&main_module, Some(ts_source), false) .await; if let Err(e) = exec_result { print_err_and_exit(e); } js_check(worker.execute("window.dispatchEvent(new Event('load'))")); let mut worker_ = worker.clone(); let result = worker.await; js_check(result); js_check(worker_.execute("window.dispatchEvent(new Event('unload'))")); } async fn bundle_command(flags: DenoFlags) { let out_file = flags.bundle_output.clone(); let (worker, state) = create_worker_and_state(flags); let main_module = state.main_module.as_ref().unwrap().clone(); debug!(">>>>> bundle_async START"); // NOTE: we need to poll `worker` otherwise TS compiler worker won't run properly let result = worker.await; js_check(result); let bundle_result = state .ts_compiler .bundle_async(state.clone(), main_module.to_string(), out_file) .await; if let Err(err) = bundle_result { debug!("diagnostics returned, exiting!"); eprintln!(""); print_err_and_exit(err); } debug!(">>>>> bundle_async END"); } async fn run_repl(flags: DenoFlags) { let (mut worker, _state) = create_worker_and_state(flags); js_check(worker.execute("bootstrapMainRuntime()")); loop { let result = worker.clone().await; if let Err(err) = result { eprintln!("{}", err.to_string()); } } } async fn run_script(flags: DenoFlags) { let (mut worker, state) = create_worker_and_state(flags); let maybe_main_module = state.main_module.as_ref(); if maybe_main_module.is_none() { print_msg_and_exit("Please provide a name to the main script to run."); } let main_module = maybe_main_module.unwrap().clone(); // Normal situation of executing a module. // Setup runtime. js_check(worker.execute("bootstrapMainRuntime()")); debug!("main_module {}", main_module); let mut worker_ = worker.clone(); let mod_result = worker.execute_mod_async(&main_module, None, false).await; if let Err(err) = mod_result { print_err_and_exit(err); } if state.flags.lock_write { if let Some(ref lockfile) = state.lockfile { let g = lockfile.lock().unwrap(); if let Err(e) = g.write() { print_err_and_exit(ErrBox::from(e)); } } else { eprintln!("--lock flag must be specified when using --lock-write"); std::process::exit(11); } } js_check(worker.execute("window.dispatchEvent(new Event('load'))")); let result = worker.await; js_check(result); js_check(worker_.execute("window.dispatchEvent(new Event('unload'))")); } async fn fmt_command(files: Option>, check: bool) { fmt::format_files(files, check); } #[tokio::main] pub async fn main() { #[cfg(windows)] ansi_term::enable_ansi_support().ok(); // For Windows 10 log::set_logger(&LOGGER).unwrap(); let args: Vec = 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()); match flags.clone().subcommand { DenoSubcommand::Bundle => bundle_command(flags).await, DenoSubcommand::Completions => {} DenoSubcommand::Eval => eval_command(flags).await, DenoSubcommand::Fetch => fetch_command(flags).await, DenoSubcommand::Format { check, files } => fmt_command(files, check).await, DenoSubcommand::Info => info_command(flags).await, DenoSubcommand::Install { dir, exe_name, module_url, args, } => install_command(flags, dir, exe_name, module_url, args).await, DenoSubcommand::Repl => run_repl(flags).await, DenoSubcommand::Run => run_script(flags).await, DenoSubcommand::Types => types_command(), _ => panic!("bad subcommand"), } }