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denoland-deno/cli/standalone/binary.rs

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::borrow::Cow;
use std::collections::BTreeMap;
use std::collections::HashMap;
use std::collections::VecDeque;
use std::env::current_exe;
use std::ffi::OsString;
use std::fs;
use std::future::Future;
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::process::Command;
use deno_ast::ModuleSpecifier;
use deno_config::workspace::PackageJsonDepResolution;
use deno_config::workspace::Workspace;
use deno_config::workspace::WorkspaceResolver;
use deno_core::anyhow::bail;
use deno_core::anyhow::Context;
use deno_core::error::AnyError;
use deno_core::futures::io::AllowStdIo;
use deno_core::futures::AsyncReadExt;
use deno_core::futures::AsyncSeekExt;
use deno_core::serde_json;
use deno_core::url::Url;
use deno_npm::NpmSystemInfo;
use deno_runtime::deno_node::PackageJson;
use deno_semver::npm::NpmVersionReqParseError;
use deno_semver::package::PackageReq;
use deno_semver::VersionReqSpecifierParseError;
use eszip::EszipRelativeFileBaseUrl;
use indexmap::IndexMap;
use log::Level;
use serde::Deserialize;
use serde::Serialize;
use crate::args::CaData;
use crate::args::CliOptions;
use crate::args::CompileFlags;
use crate::args::PackageJsonInstallDepsProvider;
use crate::args::PermissionFlags;
use crate::args::UnstableConfig;
use crate::cache::DenoDir;
use crate::file_fetcher::FileFetcher;
use crate::http_util::HttpClientProvider;
use crate::npm::CliNpmResolver;
use crate::npm::InnerCliNpmResolverRef;
use crate::standalone::virtual_fs::VfsEntry;
use crate::util::fs::canonicalize_path_maybe_not_exists;
use crate::util::progress_bar::ProgressBar;
use crate::util::progress_bar::ProgressBarStyle;
use super::virtual_fs::FileBackedVfs;
use super::virtual_fs::VfsBuilder;
use super::virtual_fs::VfsRoot;
use super::virtual_fs::VirtualDirectory;
const MAGIC_TRAILER: &[u8; 8] = b"d3n0l4nd";
#[derive(Deserialize, Serialize)]
pub enum NodeModules {
Managed {
/// Relative path for the node_modules directory in the vfs.
node_modules_dir: Option<String>,
},
Byonm {
root_node_modules_dir: String,
},
}
#[derive(Deserialize, Serialize)]
pub struct SerializedWorkspaceResolverImportMap {
pub specifier: String,
pub json: String,
}
#[derive(Deserialize, Serialize)]
pub struct SerializedWorkspaceResolver {
pub import_map: Option<SerializedWorkspaceResolverImportMap>,
pub package_jsons: BTreeMap<String, serde_json::Value>,
pub pkg_json_resolution: PackageJsonDepResolution,
}
#[derive(Deserialize, Serialize)]
pub struct Metadata {
pub argv: Vec<String>,
pub seed: Option<u64>,
pub permissions: PermissionFlags,
pub location: Option<Url>,
pub v8_flags: Vec<String>,
pub log_level: Option<Level>,
pub ca_stores: Option<Vec<String>>,
pub ca_data: Option<Vec<u8>>,
pub unsafely_ignore_certificate_errors: Option<Vec<String>>,
pub env_vars_from_env_file: HashMap<String, String>,
pub workspace_resolver: SerializedWorkspaceResolver,
pub entrypoint_key: String,
pub node_modules: Option<NodeModules>,
feat: Start warning on each use of a deprecated API (#21939) This commit introduces deprecation warnings for "Deno.*" APIs. This is gonna be quite noisy, but should tremendously help with user code updates to ensure smooth migration to Deno 2.0. The warning is printed at each unique call site to help quickly identify where code needs to be adjusted. There's some stack frame filtering going on to remove frames that are not useful to the user and would only cause confusion. The warning can be silenced using "--quiet" flag or "DENO_NO_DEPRECATION_WARNINGS" env var. "Deno.run()" API is now using this warning. Other deprecated APIs will start warning in follow up PRs. Example: ```js import { runEcho as runEcho2 } from "http://localhost:4545/run/warn_on_deprecated_api/mod.ts"; const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); async function runEcho() { const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); } await runEcho(); await runEcho(); for (let i = 0; i < 10; i++) { await runEcho(); } await runEcho2(); ``` ``` $ deno run --allow-read foo.js Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: └─ at file:///Users/ib/dev/deno/foo.js:3:16 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:13:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:14:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:17:9 hello world hello world hello world hello world hello world hello world hello world hello world hello world hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ ├ Suggestion: It appears this API is used by a remote dependency. │ Try upgrading to the latest version of that dependency. │ └ Stack trace: ├─ at runEcho (http://localhost:4545/run/warn_on_deprecated_api/mod.ts:2:18) └─ at file:///Users/ib/dev/deno/foo.js:20:7 hello world ``` Closes #21839
2024-01-18 18:30:49 -05:00
pub disable_deprecated_api_warning: bool,
pub unstable_config: UnstableConfig,
}
pub fn load_npm_vfs(root_dir_path: PathBuf) -> Result<FileBackedVfs, AnyError> {
let file_path = current_exe().unwrap();
let mut file = std::fs::File::open(file_path)?;
file.seek(SeekFrom::End(-(TRAILER_SIZE as i64)))?;
let mut trailer = [0; TRAILER_SIZE];
file.read_exact(&mut trailer)?;
let trailer = Trailer::parse(&trailer)?.unwrap();
file.seek(SeekFrom::Start(trailer.npm_vfs_pos))?;
let mut vfs_data = vec![0; trailer.npm_vfs_len() as usize];
file.read_exact(&mut vfs_data)?;
let mut dir: VirtualDirectory = serde_json::from_slice(&vfs_data)?;
// align the name of the directory with the root dir
dir.name = root_dir_path
.file_name()
.unwrap()
.to_string_lossy()
.to_string();
let fs_root = VfsRoot {
dir,
root_path: root_dir_path,
start_file_offset: trailer.npm_files_pos,
};
Ok(FileBackedVfs::new(file, fs_root))
}
fn write_binary_bytes(
writer: &mut impl Write,
original_bin: Vec<u8>,
metadata: &Metadata,
eszip: eszip::EszipV2,
npm_vfs: Option<&VirtualDirectory>,
npm_files: &Vec<Vec<u8>>,
) -> Result<(), AnyError> {
let metadata = serde_json::to_string(metadata)?.as_bytes().to_vec();
let npm_vfs = serde_json::to_string(&npm_vfs)?.as_bytes().to_vec();
let eszip_archive = eszip.into_bytes();
writer.write_all(&original_bin)?;
writer.write_all(&eszip_archive)?;
writer.write_all(&metadata)?;
writer.write_all(&npm_vfs)?;
for file in npm_files {
writer.write_all(file)?;
}
// write the trailer, which includes the positions
// of the data blocks in the file
writer.write_all(&{
let eszip_pos = original_bin.len() as u64;
let metadata_pos = eszip_pos + (eszip_archive.len() as u64);
let npm_vfs_pos = metadata_pos + (metadata.len() as u64);
let npm_files_pos = npm_vfs_pos + (npm_vfs.len() as u64);
Trailer {
eszip_pos,
metadata_pos,
npm_vfs_pos,
npm_files_pos,
}
.as_bytes()
})?;
Ok(())
}
pub fn is_standalone_binary(exe_path: &Path) -> bool {
let Ok(mut output_file) = std::fs::File::open(exe_path) else {
return false;
};
if output_file
.seek(SeekFrom::End(-(TRAILER_SIZE as i64)))
.is_err()
{
// This seek may fail because the file is too small to possibly be
// `deno compile` output.
return false;
}
let mut trailer = [0; TRAILER_SIZE];
if output_file.read_exact(&mut trailer).is_err() {
return false;
};
let (magic_trailer, _) = trailer.split_at(8);
magic_trailer == MAGIC_TRAILER
}
/// This function will try to run this binary as a standalone binary
/// produced by `deno compile`. It determines if this is a standalone
/// binary by skipping over the trailer width at the end of the file,
/// then checking for the magic trailer string `d3n0l4nd`. If found,
/// the bundle is executed. If not, this function exits with `Ok(None)`.
pub fn extract_standalone(
exe_path: &Path,
cli_args: Cow<Vec<OsString>>,
) -> Result<
Option<impl Future<Output = Result<(Metadata, eszip::EszipV2), AnyError>>>,
AnyError,
> {
// We do the first part sync so it can complete quickly
let mut file = std::fs::File::open(exe_path)?;
file.seek(SeekFrom::End(-(TRAILER_SIZE as i64)))?;
let mut trailer = [0; TRAILER_SIZE];
file.read_exact(&mut trailer)?;
let trailer = match Trailer::parse(&trailer)? {
None => return Ok(None),
Some(trailer) => trailer,
};
file.seek(SeekFrom::Start(trailer.eszip_pos))?;
let cli_args = cli_args.into_owned();
// If we have an eszip, read it out
Ok(Some(async move {
let bufreader =
deno_core::futures::io::BufReader::new(AllowStdIo::new(file));
let (eszip, loader) = eszip::EszipV2::parse(bufreader)
.await
.context("Failed to parse eszip header")?;
let mut bufreader =
loader.await.context("Failed to parse eszip archive")?;
bufreader
.seek(SeekFrom::Start(trailer.metadata_pos))
.await?;
let mut metadata = String::new();
bufreader
.take(trailer.metadata_len())
.read_to_string(&mut metadata)
.await
.context("Failed to read metadata from the current executable")?;
let mut metadata: Metadata = serde_json::from_str(&metadata).unwrap();
metadata.argv.reserve(cli_args.len() - 1);
for arg in cli_args.into_iter().skip(1) {
metadata.argv.push(arg.into_string().unwrap());
}
Ok((metadata, eszip))
}))
}
const TRAILER_SIZE: usize = std::mem::size_of::<Trailer>() + 8; // 8 bytes for the magic trailer string
struct Trailer {
eszip_pos: u64,
metadata_pos: u64,
npm_vfs_pos: u64,
npm_files_pos: u64,
}
impl Trailer {
pub fn parse(trailer: &[u8]) -> Result<Option<Trailer>, AnyError> {
let (magic_trailer, rest) = trailer.split_at(8);
if magic_trailer != MAGIC_TRAILER {
return Ok(None);
}
let (eszip_archive_pos, rest) = rest.split_at(8);
let (metadata_pos, rest) = rest.split_at(8);
let (npm_vfs_pos, npm_files_pos) = rest.split_at(8);
let eszip_archive_pos = u64_from_bytes(eszip_archive_pos)?;
let metadata_pos = u64_from_bytes(metadata_pos)?;
let npm_vfs_pos = u64_from_bytes(npm_vfs_pos)?;
let npm_files_pos = u64_from_bytes(npm_files_pos)?;
Ok(Some(Trailer {
eszip_pos: eszip_archive_pos,
metadata_pos,
npm_vfs_pos,
npm_files_pos,
}))
}
pub fn metadata_len(&self) -> u64 {
self.npm_vfs_pos - self.metadata_pos
}
pub fn npm_vfs_len(&self) -> u64 {
self.npm_files_pos - self.npm_vfs_pos
}
pub fn as_bytes(&self) -> Vec<u8> {
let mut trailer = MAGIC_TRAILER.to_vec();
trailer.write_all(&self.eszip_pos.to_be_bytes()).unwrap();
trailer.write_all(&self.metadata_pos.to_be_bytes()).unwrap();
trailer.write_all(&self.npm_vfs_pos.to_be_bytes()).unwrap();
trailer
.write_all(&self.npm_files_pos.to_be_bytes())
.unwrap();
trailer
}
}
fn u64_from_bytes(arr: &[u8]) -> Result<u64, AnyError> {
let fixed_arr: &[u8; 8] = arr
.try_into()
.context("Failed to convert the buffer into a fixed-size array")?;
Ok(u64::from_be_bytes(*fixed_arr))
}
pub fn unpack_into_dir(
exe_name: &str,
archive_name: &str,
archive_data: Vec<u8>,
is_windows: bool,
temp_dir: &tempfile::TempDir,
) -> Result<PathBuf, AnyError> {
let temp_dir_path = temp_dir.path();
let exe_ext = if is_windows { "exe" } else { "" };
let archive_path = temp_dir_path.join(exe_name).with_extension("zip");
let exe_path = temp_dir_path.join(exe_name).with_extension(exe_ext);
assert!(!exe_path.exists());
let archive_ext = Path::new(archive_name)
.extension()
.and_then(|ext| ext.to_str())
.unwrap();
let unpack_status = match archive_ext {
"zip" if cfg!(windows) => {
fs::write(&archive_path, &archive_data)?;
Command::new("tar.exe")
.arg("xf")
.arg(&archive_path)
.arg("-C")
.arg(temp_dir_path)
.spawn()
.map_err(|err| {
if err.kind() == std::io::ErrorKind::NotFound {
std::io::Error::new(
std::io::ErrorKind::NotFound,
"`tar.exe` was not found in your PATH",
)
} else {
err
}
})?
.wait()?
}
"zip" => {
fs::write(&archive_path, &archive_data)?;
Command::new("unzip")
.current_dir(temp_dir_path)
.arg(&archive_path)
.spawn()
.map_err(|err| {
if err.kind() == std::io::ErrorKind::NotFound {
std::io::Error::new(
std::io::ErrorKind::NotFound,
"`unzip` was not found in your PATH, please install `unzip`",
)
} else {
err
}
})?
.wait()?
}
ext => bail!("Unsupported archive type: '{ext}'"),
};
if !unpack_status.success() {
bail!("Failed to unpack archive.");
}
assert!(exe_path.exists());
fs::remove_file(&archive_path)?;
Ok(exe_path)
}
pub struct DenoCompileBinaryWriter<'a> {
deno_dir: &'a DenoDir,
file_fetcher: &'a FileFetcher,
http_client_provider: &'a HttpClientProvider,
npm_resolver: &'a dyn CliNpmResolver,
workspace_resolver: &'a WorkspaceResolver,
npm_system_info: NpmSystemInfo,
}
impl<'a> DenoCompileBinaryWriter<'a> {
#[allow(clippy::too_many_arguments)]
pub fn new(
deno_dir: &'a DenoDir,
file_fetcher: &'a FileFetcher,
http_client_provider: &'a HttpClientProvider,
npm_resolver: &'a dyn CliNpmResolver,
workspace_resolver: &'a WorkspaceResolver,
npm_system_info: NpmSystemInfo,
) -> Self {
Self {
deno_dir,
file_fetcher,
http_client_provider,
npm_resolver,
workspace_resolver,
npm_system_info,
}
}
pub async fn write_bin(
&self,
writer: &mut impl Write,
eszip: eszip::EszipV2,
root_dir_url: EszipRelativeFileBaseUrl<'_>,
entrypoint: &ModuleSpecifier,
compile_flags: &CompileFlags,
cli_options: &CliOptions,
) -> Result<(), AnyError> {
// Select base binary based on target
let mut original_binary = self.get_base_binary(compile_flags).await?;
if compile_flags.no_terminal {
let target = compile_flags.resolve_target();
if !target.contains("windows") {
bail!(
"The `--no-terminal` flag is only available when targeting Windows (current: {})",
target,
)
}
set_windows_binary_to_gui(&mut original_binary)?;
}
self.write_standalone_binary(
writer,
original_binary,
eszip,
root_dir_url,
entrypoint,
cli_options,
compile_flags,
)
}
async fn get_base_binary(
&self,
compile_flags: &CompileFlags,
) -> Result<Vec<u8>, AnyError> {
// Used for testing.
//
// Phase 2 of the 'min sized' deno compile RFC talks
// about adding this as a flag.
if let Some(path) = std::env::var_os("DENORT_BIN") {
return std::fs::read(&path).with_context(|| {
format!("Could not find denort at '{}'", path.to_string_lossy())
});
}
let target = compile_flags.resolve_target();
let binary_name = format!("denort-{target}.zip");
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 = self.deno_dir.dl_folder_path();
let binary_path = download_directory.join(&binary_path_suffix);
if !binary_path.exists() {
self
.download_base_binary(&download_directory, &binary_path_suffix)
.await?;
}
let archive_data = std::fs::read(binary_path)?;
let temp_dir = tempfile::TempDir::new()?;
let base_binary_path = unpack_into_dir(
"denort",
&binary_name,
archive_data,
target.contains("windows"),
&temp_dir,
)?;
let base_binary = std::fs::read(base_binary_path)?;
drop(temp_dir); // delete the temp dir
Ok(base_binary)
}
async fn download_base_binary(
&self,
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);
self
.http_client_provider
.get_or_create()?
.download_with_progress(download_url, None, &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.
#[allow(clippy::too_many_arguments)]
fn write_standalone_binary(
&self,
writer: &mut impl Write,
original_bin: Vec<u8>,
mut eszip: eszip::EszipV2,
root_dir_url: EszipRelativeFileBaseUrl<'_>,
entrypoint: &ModuleSpecifier,
cli_options: &CliOptions,
compile_flags: &CompileFlags,
) -> Result<(), AnyError> {
let ca_data = match cli_options.ca_data() {
Some(CaData::File(ca_file)) => Some(
std::fs::read(ca_file)
.with_context(|| format!("Reading: {ca_file}"))?,
),
Some(CaData::Bytes(bytes)) => Some(bytes.clone()),
None => None,
};
let root_path = root_dir_url.inner().to_file_path().unwrap();
let (npm_vfs, npm_files, node_modules) = match self.npm_resolver.as_inner()
{
InnerCliNpmResolverRef::Managed(managed) => {
let snapshot =
managed.serialized_valid_snapshot_for_system(&self.npm_system_info);
if !snapshot.as_serialized().packages.is_empty() {
let (root_dir, files) = self
.build_vfs(&root_path, cli_options)?
.into_dir_and_files();
eszip.add_npm_snapshot(snapshot);
(
Some(root_dir),
files,
Some(NodeModules::Managed {
node_modules_dir: self.npm_resolver.root_node_modules_path().map(
|path| {
root_dir_url
.specifier_key(
&ModuleSpecifier::from_directory_path(path).unwrap(),
)
.into_owned()
},
),
}),
)
} else {
(None, Vec::new(), None)
}
}
InnerCliNpmResolverRef::Byonm(resolver) => {
let (root_dir, files) = self
.build_vfs(&root_path, cli_options)?
.into_dir_and_files();
(
Some(root_dir),
files,
Some(NodeModules::Byonm {
root_node_modules_dir: root_dir_url
.specifier_key(
&ModuleSpecifier::from_directory_path(
// will always be set for byonm
resolver.root_node_modules_path().unwrap(),
)
.unwrap(),
)
.into_owned(),
}),
)
}
};
let env_vars_from_env_file = match cli_options.env_file_name() {
Some(env_filename) => {
log::info!("{} Environment variables from the file \"{}\" were embedded in the generated executable file", crate::colors::yellow("Warning"), env_filename);
get_file_env_vars(env_filename.to_string())?
}
None => Default::default(),
};
let metadata = Metadata {
argv: compile_flags.args.clone(),
seed: cli_options.seed(),
location: cli_options.location_flag().clone(),
permissions: cli_options.permission_flags().clone(),
v8_flags: cli_options.v8_flags().clone(),
unsafely_ignore_certificate_errors: cli_options
.unsafely_ignore_certificate_errors()
.clone(),
log_level: cli_options.log_level(),
ca_stores: cli_options.ca_stores().clone(),
ca_data,
env_vars_from_env_file,
entrypoint_key: root_dir_url.specifier_key(entrypoint).into_owned(),
workspace_resolver: SerializedWorkspaceResolver {
import_map: self.workspace_resolver.maybe_import_map().map(|i| {
SerializedWorkspaceResolverImportMap {
specifier: if i.base_url().scheme() == "file" {
root_dir_url.specifier_key(i.base_url()).into_owned()
} else {
// just make a remote url local
"deno.json".to_string()
},
json: i.to_json(),
}
}),
package_jsons: self
.workspace_resolver
.package_jsons()
.map(|pkg_json| {
(
root_dir_url
.specifier_key(&pkg_json.specifier())
.into_owned(),
serde_json::to_value(pkg_json).unwrap(),
)
})
.collect(),
pkg_json_resolution: self.workspace_resolver.pkg_json_dep_resolution(),
},
node_modules,
feat: Start warning on each use of a deprecated API (#21939) This commit introduces deprecation warnings for "Deno.*" APIs. This is gonna be quite noisy, but should tremendously help with user code updates to ensure smooth migration to Deno 2.0. The warning is printed at each unique call site to help quickly identify where code needs to be adjusted. There's some stack frame filtering going on to remove frames that are not useful to the user and would only cause confusion. The warning can be silenced using "--quiet" flag or "DENO_NO_DEPRECATION_WARNINGS" env var. "Deno.run()" API is now using this warning. Other deprecated APIs will start warning in follow up PRs. Example: ```js import { runEcho as runEcho2 } from "http://localhost:4545/run/warn_on_deprecated_api/mod.ts"; const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); async function runEcho() { const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); } await runEcho(); await runEcho(); for (let i = 0; i < 10; i++) { await runEcho(); } await runEcho2(); ``` ``` $ deno run --allow-read foo.js Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: └─ at file:///Users/ib/dev/deno/foo.js:3:16 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:13:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:14:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:17:9 hello world hello world hello world hello world hello world hello world hello world hello world hello world hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ ├ Suggestion: It appears this API is used by a remote dependency. │ Try upgrading to the latest version of that dependency. │ └ Stack trace: ├─ at runEcho (http://localhost:4545/run/warn_on_deprecated_api/mod.ts:2:18) └─ at file:///Users/ib/dev/deno/foo.js:20:7 hello world ``` Closes #21839
2024-01-18 18:30:49 -05:00
disable_deprecated_api_warning: cli_options
.disable_deprecated_api_warning,
unstable_config: UnstableConfig {
legacy_flag_enabled: cli_options.legacy_unstable_flag(),
bare_node_builtins: cli_options.unstable_bare_node_builtins(),
byonm: cli_options.use_byonm(),
sloppy_imports: cli_options.unstable_sloppy_imports(),
features: cli_options.unstable_features(),
},
};
write_binary_bytes(
writer,
original_bin,
&metadata,
eszip,
npm_vfs.as_ref(),
&npm_files,
)
}
fn build_vfs(
&self,
root_path: &Path,
cli_options: &CliOptions,
) -> Result<VfsBuilder, AnyError> {
fn maybe_warn_different_system(system_info: &NpmSystemInfo) {
if system_info != &NpmSystemInfo::default() {
log::warn!("{} The node_modules directory may be incompatible with the target system.", crate::colors::yellow("Warning"));
}
}
match self.npm_resolver.as_inner() {
InnerCliNpmResolverRef::Managed(npm_resolver) => {
if let Some(node_modules_path) = npm_resolver.root_node_modules_path() {
maybe_warn_different_system(&self.npm_system_info);
let mut builder = VfsBuilder::new(root_path.to_path_buf())?;
builder.add_dir_recursive(node_modules_path)?;
Ok(builder)
} else {
// DO NOT include the user's registry url as it may contain credentials,
// but also don't make this dependent on the registry url
let root_path = npm_resolver.global_cache_root_folder();
let mut builder = VfsBuilder::new(root_path)?;
for package in npm_resolver.all_system_packages(&self.npm_system_info)
{
let folder =
npm_resolver.resolve_pkg_folder_from_pkg_id(&package.id)?;
builder.add_dir_recursive(&folder)?;
}
// Flatten all the registries folders into a single "node_modules/localhost" folder
// that will be used by denort when loading the npm cache. This avoids us exposing
// the user's private registry information and means we don't have to bother
// serializing all the different registry config into the binary.
builder.with_root_dir(|root_dir| {
root_dir.name = "node_modules".to_string();
let mut new_entries = Vec::with_capacity(root_dir.entries.len());
let mut localhost_entries = IndexMap::new();
for entry in std::mem::take(&mut root_dir.entries) {
match entry {
VfsEntry::Dir(dir) => {
for entry in dir.entries {
log::debug!(
"Flattening {} into node_modules",
entry.name()
);
if let Some(existing) =
localhost_entries.insert(entry.name().to_string(), entry)
{
panic!(
"Unhandled scenario where a duplicate entry was found: {:?}",
existing
);
}
}
}
VfsEntry::File(_) | VfsEntry::Symlink(_) => {
new_entries.push(entry);
}
}
}
new_entries.push(VfsEntry::Dir(VirtualDirectory {
name: "localhost".to_string(),
entries: localhost_entries.into_iter().map(|(_, v)| v).collect(),
}));
// needs to be sorted by name
new_entries.sort_by(|a, b| a.name().cmp(b.name()));
root_dir.entries = new_entries;
});
Ok(builder)
}
}
InnerCliNpmResolverRef::Byonm(_) => {
maybe_warn_different_system(&self.npm_system_info);
let mut builder = VfsBuilder::new(root_path.to_path_buf())?;
for pkg_json in cli_options.workspace.package_jsons() {
builder.add_file_at_path(&pkg_json.path)?;
}
// traverse and add all the node_modules directories in the workspace
let mut pending_dirs = VecDeque::new();
pending_dirs.push_back(
cli_options
.workspace
.root_folder()
.0
.to_file_path()
.unwrap(),
);
while let Some(pending_dir) = pending_dirs.pop_front() {
let entries = fs::read_dir(&pending_dir).with_context(|| {
format!("Failed reading: {}", pending_dir.display())
})?;
for entry in entries {
let entry = entry?;
let path = entry.path();
if !path.is_dir() {
continue;
}
if path.ends_with("node_modules") {
builder.add_dir_recursive(&path)?;
} else {
pending_dirs.push_back(path);
}
}
}
Ok(builder)
}
}
}
}
/// This function returns the environment variables specified
/// in the passed environment file.
fn get_file_env_vars(
filename: String,
) -> Result<HashMap<String, String>, dotenvy::Error> {
let mut file_env_vars = HashMap::new();
for item in dotenvy::from_filename_iter(filename)? {
let Ok((key, val)) = item else {
continue; // this failure will be warned about on load
};
file_env_vars.insert(key, val);
}
Ok(file_env_vars)
}
/// This function sets the subsystem field in the PE header to 2 (GUI subsystem)
/// For more information about the PE header: https://learn.microsoft.com/en-us/windows/win32/debug/pe-format
fn set_windows_binary_to_gui(bin: &mut [u8]) -> Result<(), AnyError> {
// Get the PE header offset located in an i32 found at offset 60
// See: https://learn.microsoft.com/en-us/windows/win32/debug/pe-format#ms-dos-stub-image-only
let start_pe = u32::from_le_bytes((bin[60..64]).try_into()?);
// Get image type (PE32 or PE32+) indicates whether the binary is 32 or 64 bit
// The used offset and size values can be found here:
// https://learn.microsoft.com/en-us/windows/win32/debug/pe-format#optional-header-image-only
let start_32 = start_pe as usize + 28;
let magic_32 =
u16::from_le_bytes(bin[(start_32)..(start_32 + 2)].try_into()?);
let start_64 = start_pe as usize + 24;
let magic_64 =
u16::from_le_bytes(bin[(start_64)..(start_64 + 2)].try_into()?);
// Take the standard fields size for the current architecture (32 or 64 bit)
// This is the ofset for the Windows-Specific fields
let standard_fields_size = if magic_32 == 0x10b {
28
} else if magic_64 == 0x20b {
24
} else {
bail!("Could not find a matching magic field in the PE header")
};
// Set the subsystem field (offset 68) to 2 (GUI subsystem)
// For all possible options, see: https://learn.microsoft.com/en-us/windows/win32/debug/pe-format#optional-header-windows-specific-fields-image-only
let subsystem_offset = 68;
let subsystem_start =
start_pe as usize + standard_fields_size + subsystem_offset;
let subsystem: u16 = 2;
bin[(subsystem_start)..(subsystem_start + 2)]
.copy_from_slice(&subsystem.to_le_bytes());
Ok(())
}