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denoland-deno/cli/tools/compile.rs
David Sherret 842e29057d
refactor: break out ModuleInfoCache from ParsedSourceCache (#20977)
As title. This will help use the two independently from the other, which
will help in an upcoming deno doc PR where I need to parse the source
files with scope analysis.
2023-10-25 18:13:22 -04:00

273 lines
8 KiB
Rust

// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
use crate::args::CompileFlags;
use crate::args::Flags;
use crate::factory::CliFactory;
use crate::standalone::is_standalone_binary;
use crate::util::path::path_has_trailing_slash;
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_graph::GraphKind;
use deno_runtime::colors;
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 factory = CliFactory::from_flags(flags).await?;
let cli_options = factory.cli_options();
let module_graph_builder = factory.module_graph_builder().await?;
let parsed_source_cache = factory.parsed_source_cache();
let binary_writer = factory.create_compile_binary_writer().await?;
let module_specifier = cli_options.resolve_main_module()?;
let module_roots = {
let mut vec = Vec::with_capacity(compile_flags.include.len() + 1);
vec.push(module_specifier.clone());
for side_module in &compile_flags.include {
vec.push(resolve_url_or_path(side_module, cli_options.initial_cwd())?);
}
vec
};
let output_path = resolve_compile_executable_output_path(
&compile_flags,
cli_options.initial_cwd(),
)
.await?;
let graph = Arc::try_unwrap(
module_graph_builder
.create_graph_and_maybe_check(module_roots.clone())
.await?,
)
.unwrap();
let graph = if cli_options.type_check_mode().is_true() {
// In this case, the previous graph creation did type checking, which will
// create a module graph with types information in it. We don't want to
// store that in the eszip so create a code only module graph from scratch.
module_graph_builder
.create_graph(GraphKind::CodeOnly, module_roots)
.await?
} else {
graph
};
let parser = parsed_source_cache.as_capturing_parser();
let eszip = eszip::EszipV2::from_graph(graph, &parser, Default::default())?;
log::info!(
"{} {} to {}",
colors::green("Compile"),
module_specifier.to_string(),
output_path.display(),
);
validate_output_path(&output_path)?;
let mut file = std::fs::File::create(&output_path)?;
binary_writer
.write_bin(
&mut file,
eszip,
&module_specifier,
&compile_flags,
cli_options,
)
.await
.with_context(|| format!("Writing {}", output_path.display()))?;
drop(file);
// set it as executable
#[cfg(unix)]
{
use std::os::unix::fs::PermissionsExt;
let perms = std::fs::Permissions::from_mode(0o777);
std::fs::set_permissions(output_path, perms)?;
}
Ok(())
}
/// This function writes out a final binary to specified path. If output path
/// is not already standalone binary it will return error instead.
fn validate_output_path(output_path: &Path) -> 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 <file-path>` flag to ",
"provide an alternative name."
),
output_path.display()
);
}
// Make sure we don't overwrite any file not created by Deno compiler because
// this filename is chosen automatically in some cases.
if !is_standalone_binary(output_path) {
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 <file-path>` flag to provide an alternative name."
),
output_path.display()
);
}
// Remove file if it was indeed a deno compiled binary, to avoid corruption
// (see https://github.com/denoland/deno/issues/10310)
std::fs::remove_file(output_path)?;
} else {
let output_base = &output_path.parent().unwrap();
if output_base.exists() && output_base.is_file() {
bail!(
concat!(
"Could not compile to file '{}' because its parent directory ",
"is an existing file. You can use the `--output <file-path>` flag to ",
"provide an alternative name.",
),
output_base.display(),
);
}
std::fs::create_dir_all(output_base)?;
}
Ok(())
}
async fn resolve_compile_executable_output_path(
compile_flags: &CompileFlags,
current_dir: &Path,
) -> Result<PathBuf, AnyError> {
let module_specifier =
resolve_url_or_path(&compile_flags.source_file, current_dir)?;
let mut output = compile_flags.output.clone();
if let Some(out) = output.as_ref() {
if path_has_trailing_slash(out) {
if let Some(infer_file_name) = infer_name_from_url(&module_specifier)
.await
.map(PathBuf::from)
{
output = Some(out.join(infer_file_name));
}
} else {
output = Some(out.to_path_buf());
}
}
if output.is_none() {
output = infer_name_from_url(&module_specifier)
.await
.map(PathBuf::from)
}
output.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<String>,
) -> 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::*;
#[tokio::test]
async 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()),
no_terminal: false,
include: vec![],
},
&std::env::current_dir().unwrap(),
)
.await
.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");
}
#[tokio::test]
async 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()),
include: vec![],
no_terminal: false,
},
&std::env::current_dir().unwrap(),
)
.await
.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");
}
}