// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license. use crate::args::CaData; use crate::args::CompileFlags; use crate::args::Flags; use crate::cache::DenoDir; use crate::graph_util::create_graph_and_maybe_check; use crate::graph_util::error_for_any_npm_specifier; use crate::http_util::HttpClient; use crate::standalone::Metadata; use crate::standalone::MAGIC_TRAILER; use crate::util::path::path_has_trailing_slash; use crate::util::progress_bar::ProgressBar; use crate::util::progress_bar::ProgressBarStyle; use crate::ProcState; use deno_core::anyhow::bail; use deno_core::anyhow::Context; use deno_core::error::generic_error; use deno_core::error::AnyError; use deno_core::resolve_url_or_path; use deno_core::serde_json; use deno_graph::ModuleSpecifier; use deno_runtime::colors; use std::env; use std::fs; use std::fs::File; use std::io::Read; use std::io::Seek; use std::io::SeekFrom; use std::io::Write; use std::path::Path; use std::path::PathBuf; use std::sync::Arc; use super::installer::infer_name_from_url; pub async fn compile( flags: Flags, compile_flags: CompileFlags, ) -> Result<(), AnyError> { let ps = ProcState::build(flags).await?; let module_specifier = resolve_url_or_path(&compile_flags.source_file)?; let deno_dir = &ps.dir; let output_path = resolve_compile_executable_output_path(&compile_flags)?; let graph = Arc::try_unwrap( create_graph_and_maybe_check(module_specifier.clone(), &ps).await?, ) .unwrap(); // at the moment, we don't support npm specifiers in deno_compile, so show an error error_for_any_npm_specifier(&graph)?; graph.valid()?; let parser = ps.parsed_source_cache.as_capturing_parser(); let eszip = eszip::EszipV2::from_graph(graph, &parser, Default::default())?; log::info!( "{} {}", colors::green("Compile"), module_specifier.to_string() ); // Select base binary based on target let original_binary = get_base_binary(&ps.http_client, deno_dir, compile_flags.target.clone()) .await?; let final_bin = create_standalone_binary( original_binary, eszip, module_specifier, &compile_flags, ps, ) .await?; log::info!("{} {}", colors::green("Emit"), output_path.display()); write_standalone_binary(output_path, final_bin).await?; Ok(()) } async fn get_base_binary( client: &HttpClient, deno_dir: &DenoDir, target: Option, ) -> Result, AnyError> { if target.is_none() { let path = std::env::current_exe()?; return Ok(tokio::fs::read(path).await?); } let target = target.unwrap_or_else(|| env!("TARGET").to_string()); let binary_name = format!("deno-{}.zip", target); let binary_path_suffix = if crate::version::is_canary() { format!("canary/{}/{}", crate::version::GIT_COMMIT_HASH, binary_name) } else { format!("release/v{}/{}", env!("CARGO_PKG_VERSION"), binary_name) }; let download_directory = deno_dir.dl_folder_path(); let binary_path = download_directory.join(&binary_path_suffix); if !binary_path.exists() { download_base_binary(client, &download_directory, &binary_path_suffix) .await?; } let archive_data = tokio::fs::read(binary_path).await?; let temp_dir = secure_tempfile::TempDir::new()?; let base_binary_path = crate::tools::upgrade::unpack_into_dir( archive_data, target.contains("windows"), &temp_dir, )?; let base_binary = tokio::fs::read(base_binary_path).await?; drop(temp_dir); // delete the temp dir Ok(base_binary) } async fn download_base_binary( client: &HttpClient, output_directory: &Path, binary_path_suffix: &str, ) -> Result<(), AnyError> { let download_url = format!("https://dl.deno.land/{}", binary_path_suffix); let maybe_bytes = { let progress_bars = ProgressBar::new(ProgressBarStyle::DownloadBars); let progress = progress_bars.update(&download_url); client .download_with_progress(download_url, &progress) .await? }; let bytes = match maybe_bytes { Some(bytes) => bytes, None => { log::info!("Download could not be found, aborting"); std::process::exit(1) } }; std::fs::create_dir_all(output_directory)?; let output_path = output_directory.join(binary_path_suffix); std::fs::create_dir_all(output_path.parent().unwrap())?; tokio::fs::write(output_path, bytes).await?; Ok(()) } /// This functions creates a standalone deno binary by appending a bundle /// and magic trailer to the currently executing binary. async fn create_standalone_binary( mut original_bin: Vec, eszip: eszip::EszipV2, entrypoint: ModuleSpecifier, compile_flags: &CompileFlags, ps: ProcState, ) -> Result, AnyError> { let mut eszip_archive = eszip.into_bytes(); let ca_data = match ps.options.ca_data() { Some(CaData::File(ca_file)) => { Some(fs::read(ca_file).with_context(|| format!("Reading: {}", ca_file))?) } Some(CaData::Bytes(bytes)) => Some(bytes.clone()), None => None, }; let maybe_import_map = ps .options .resolve_import_map(&ps.file_fetcher) .await? .map(|import_map| (import_map.base_url().clone(), import_map.to_json())); let metadata = Metadata { argv: compile_flags.args.clone(), unstable: ps.options.unstable(), seed: ps.options.seed(), location: ps.options.location_flag().clone(), permissions: ps.options.permissions_options(), v8_flags: ps.options.v8_flags().clone(), unsafely_ignore_certificate_errors: ps .options .unsafely_ignore_certificate_errors() .clone(), log_level: ps.options.log_level(), ca_stores: ps.options.ca_stores().clone(), ca_data, entrypoint, maybe_import_map, }; let mut metadata = serde_json::to_string(&metadata)?.as_bytes().to_vec(); let eszip_pos = original_bin.len(); let metadata_pos = eszip_pos + eszip_archive.len(); let mut trailer = MAGIC_TRAILER.to_vec(); trailer.write_all(&eszip_pos.to_be_bytes())?; trailer.write_all(&metadata_pos.to_be_bytes())?; let mut final_bin = Vec::with_capacity( original_bin.len() + eszip_archive.len() + trailer.len(), ); final_bin.append(&mut original_bin); final_bin.append(&mut eszip_archive); final_bin.append(&mut metadata); final_bin.append(&mut trailer); Ok(final_bin) } /// This function writes out a final binary to specified path. If output path /// is not already standalone binary it will return error instead. async fn write_standalone_binary( output_path: PathBuf, final_bin: Vec, ) -> Result<(), AnyError> { if output_path.exists() { // If the output is a directory, throw error if output_path.is_dir() { bail!( concat!( "Could not compile to file '{}' because a directory exists with ", "the same name. You can use the `--output ` flag to ", "provide an alternative name." ), output_path.display() ); } // Make sure we don't overwrite any file not created by Deno compiler. // Check for magic trailer in last 24 bytes. let mut has_trailer = false; let mut output_file = File::open(&output_path)?; // This seek may fail because the file is too small to possibly be // `deno compile` output. if output_file.seek(SeekFrom::End(-24)).is_ok() { let mut trailer = [0; 24]; output_file.read_exact(&mut trailer)?; let (magic_trailer, _) = trailer.split_at(8); has_trailer = magic_trailer == MAGIC_TRAILER; } if !has_trailer { bail!( concat!( "Could not compile to file '{}' because the file already exists ", "and cannot be overwritten. Please delete the existing file or ", "use the `--output ` flag to ", "provide an alternative name.", ), output_base.display(), ); } tokio::fs::create_dir_all(output_base).await?; } tokio::fs::write(&output_path, final_bin).await?; #[cfg(unix)] { use std::os::unix::fs::PermissionsExt; let perms = std::fs::Permissions::from_mode(0o777); tokio::fs::set_permissions(output_path, perms).await?; } Ok(()) } fn resolve_compile_executable_output_path( compile_flags: &CompileFlags, ) -> Result { let module_specifier = resolve_url_or_path(&compile_flags.source_file)?; compile_flags.output.as_ref().and_then(|output| { if path_has_trailing_slash(output) { let infer_file_name = infer_name_from_url(&module_specifier).map(PathBuf::from)?; Some(output.join(infer_file_name)) } else { Some(output.to_path_buf()) } }).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.", )).map(|output| { get_os_specific_filepath(output, &compile_flags.target) }) } fn get_os_specific_filepath( output: PathBuf, target: &Option, ) -> PathBuf { let is_windows = match target { Some(target) => target.contains("windows"), None => cfg!(windows), }; if is_windows && output.extension().unwrap_or_default() != "exe" { if let Some(ext) = output.extension() { // keep version in my-exe-0.1.0 -> my-exe-0.1.0.exe output.with_extension(format!("{}.exe", ext.to_string_lossy())) } else { output.with_extension("exe") } } else { output } } #[cfg(test)] mod test { pub use super::*; #[test] fn resolve_compile_executable_output_path_target_linux() { let path = resolve_compile_executable_output_path(&CompileFlags { source_file: "mod.ts".to_string(), output: Some(PathBuf::from("./file")), args: Vec::new(), target: Some("x86_64-unknown-linux-gnu".to_string()), }) .unwrap(); // no extension, no matter what the operating system is // because the target was specified as linux // https://github.com/denoland/deno/issues/9667 assert_eq!(path.file_name().unwrap(), "file"); } #[test] fn resolve_compile_executable_output_path_target_windows() { let path = resolve_compile_executable_output_path(&CompileFlags { source_file: "mod.ts".to_string(), output: Some(PathBuf::from("./file")), args: Vec::new(), target: Some("x86_64-pc-windows-msvc".to_string()), }) .unwrap(); assert_eq!(path.file_name().unwrap(), "file.exe"); } #[test] fn test_os_specific_file_path() { fn run_test(path: &str, target: Option<&str>, expected: &str) { assert_eq!( get_os_specific_filepath( PathBuf::from(path), &target.map(|s| s.to_string()) ), PathBuf::from(expected) ); } if cfg!(windows) { run_test("C:\\my-exe", None, "C:\\my-exe.exe"); run_test("C:\\my-exe.exe", None, "C:\\my-exe.exe"); run_test("C:\\my-exe-0.1.2", None, "C:\\my-exe-0.1.2.exe"); } else { run_test("my-exe", Some("linux"), "my-exe"); run_test("my-exe-0.1.2", Some("linux"), "my-exe-0.1.2"); } run_test("C:\\my-exe", Some("windows"), "C:\\my-exe.exe"); run_test("C:\\my-exe.exe", Some("windows"), "C:\\my-exe.exe"); run_test("C:\\my-exe.0.1.2", Some("windows"), "C:\\my-exe.0.1.2.exe"); run_test("my-exe-0.1.2", Some("linux"), "my-exe-0.1.2"); } }