//! Various utility functions used throughout rustbuild. //! //! Simple things like testing the various filesystem operations here and there, //! not a lot of interesting happenings here unfortunately. use build_helper::util::{fail, try_run}; use std::env; use std::fs; use std::io; use std::path::{Path, PathBuf}; use std::process::{Command, Stdio}; use std::str; use std::time::{Instant, SystemTime, UNIX_EPOCH}; use crate::builder::Builder; use crate::config::{Config, TargetSelection}; use crate::OnceCell; /// A helper macro to `unwrap` a result except also print out details like: /// /// * The file/line of the panic /// * The expression that failed /// * The error itself /// /// This is currently used judiciously throughout the build system rather than /// using a `Result` with `try!`, but this may change one day... #[macro_export] macro_rules! t { ($e:expr) => { match $e { Ok(e) => e, Err(e) => panic!("{} failed with {}", stringify!($e), e), } }; // it can show extra info in the second parameter ($e:expr, $extra:expr) => { match $e { Ok(e) => e, Err(e) => panic!("{} failed with {} ({:?})", stringify!($e), e, $extra), } }; } pub use t; /// Given an executable called `name`, return the filename for the /// executable for a particular target. pub fn exe(name: &str, target: TargetSelection) -> String { if target.contains("windows") { format!("{name}.exe") } else if target.contains("uefi") { format!("{name}.efi") } else { name.to_string() } } /// Returns `true` if the file name given looks like a dynamic library. pub fn is_dylib(name: &str) -> bool { name.ends_with(".dylib") || name.ends_with(".so") || name.ends_with(".dll") } /// Returns `true` if the file name given looks like a debug info file pub fn is_debug_info(name: &str) -> bool { // FIXME: consider split debug info on other platforms (e.g., Linux, macOS) name.ends_with(".pdb") } /// Returns the corresponding relative library directory that the compiler's /// dylibs will be found in. pub fn libdir(target: TargetSelection) -> &'static str { if target.contains("windows") { "bin" } else { "lib" } } /// Adds a list of lookup paths to `cmd`'s dynamic library lookup path. /// If the dylib_path_var is already set for this cmd, the old value will be overwritten! pub fn add_dylib_path(path: Vec, cmd: &mut Command) { let mut list = dylib_path(); for path in path { list.insert(0, path); } cmd.env(dylib_path_var(), t!(env::join_paths(list))); } include!("dylib_util.rs"); /// Adds a list of lookup paths to `cmd`'s link library lookup path. pub fn add_link_lib_path(path: Vec, cmd: &mut Command) { let mut list = link_lib_path(); for path in path { list.insert(0, path); } cmd.env(link_lib_path_var(), t!(env::join_paths(list))); } /// Returns the environment variable which the link library lookup path /// resides in for this platform. fn link_lib_path_var() -> &'static str { if cfg!(target_env = "msvc") { "LIB" } else { "LIBRARY_PATH" } } /// Parses the `link_lib_path_var()` environment variable, returning a list of /// paths that are members of this lookup path. fn link_lib_path() -> Vec { let var = match env::var_os(link_lib_path_var()) { Some(v) => v, None => return vec![], }; env::split_paths(&var).collect() } pub struct TimeIt(bool, Instant); /// Returns an RAII structure that prints out how long it took to drop. pub fn timeit(builder: &Builder<'_>) -> TimeIt { TimeIt(builder.config.dry_run(), Instant::now()) } impl Drop for TimeIt { fn drop(&mut self) { let time = self.1.elapsed(); if !self.0 { println!("\tfinished in {}.{:03} seconds", time.as_secs(), time.subsec_millis()); } } } /// Used for download caching pub(crate) fn program_out_of_date(stamp: &Path, key: &str) -> bool { if !stamp.exists() { return true; } t!(fs::read_to_string(stamp)) != key } /// Symlinks two directories, using junctions on Windows and normal symlinks on /// Unix. pub fn symlink_dir(config: &Config, original: &Path, link: &Path) -> io::Result<()> { if config.dry_run() { return Ok(()); } let _ = fs::remove_dir(link); return symlink_dir_inner(original, link); #[cfg(not(windows))] fn symlink_dir_inner(original: &Path, link: &Path) -> io::Result<()> { use std::os::unix::fs; fs::symlink(original, link) } #[cfg(windows)] fn symlink_dir_inner(target: &Path, junction: &Path) -> io::Result<()> { junction::create(&target, &junction) } } pub fn forcing_clang_based_tests() -> bool { if let Some(var) = env::var_os("RUSTBUILD_FORCE_CLANG_BASED_TESTS") { match &var.to_string_lossy().to_lowercase()[..] { "1" | "yes" | "on" => true, "0" | "no" | "off" => false, other => { // Let's make sure typos don't go unnoticed panic!( "Unrecognized option '{other}' set in \ RUSTBUILD_FORCE_CLANG_BASED_TESTS" ) } } } else { false } } pub fn use_host_linker(target: TargetSelection) -> bool { // FIXME: this information should be gotten by checking the linker flavor // of the rustc target !(target.contains("emscripten") || target.contains("wasm32") || target.contains("nvptx") || target.contains("fortanix") || target.contains("fuchsia") || target.contains("bpf") || target.contains("switch")) } pub fn is_valid_test_suite_arg<'a, P: AsRef>( path: &'a Path, suite_path: P, builder: &Builder<'_>, ) -> Option<&'a str> { let suite_path = suite_path.as_ref(); let path = match path.strip_prefix(".") { Ok(p) => p, Err(_) => path, }; if !path.starts_with(suite_path) { return None; } let abs_path = builder.src.join(path); let exists = abs_path.is_dir() || abs_path.is_file(); if !exists { panic!( "Invalid test suite filter \"{}\": file or directory does not exist", abs_path.display() ); } // Since test suite paths are themselves directories, if we don't // specify a directory or file, we'll get an empty string here // (the result of the test suite directory without its suite prefix). // Therefore, we need to filter these out, as only the first --test-args // flag is respected, so providing an empty --test-args conflicts with // any following it. match path.strip_prefix(suite_path).ok().and_then(|p| p.to_str()) { Some(s) if !s.is_empty() => Some(s), _ => None, } } pub fn run(cmd: &mut Command, print_cmd_on_fail: bool) { if try_run(cmd, print_cmd_on_fail).is_err() { crate::exit!(1); } } pub fn check_run(cmd: &mut Command, print_cmd_on_fail: bool) -> bool { let status = match cmd.status() { Ok(status) => status, Err(e) => { println!("failed to execute command: {cmd:?}\nerror: {e}"); return false; } }; if !status.success() && print_cmd_on_fail { println!( "\n\ncommand did not execute successfully: {cmd:?}\n\ expected success, got: {status}\n\n" ); } status.success() } pub fn run_suppressed(cmd: &mut Command) { if !try_run_suppressed(cmd) { crate::exit!(1); } } pub fn try_run_suppressed(cmd: &mut Command) -> bool { let output = match cmd.output() { Ok(status) => status, Err(e) => fail(&format!("failed to execute command: {cmd:?}\nerror: {e}")), }; if !output.status.success() { println!( "\n\ncommand did not execute successfully: {:?}\n\ expected success, got: {}\n\n\ stdout ----\n{}\n\ stderr ----\n{}\n\n", cmd, output.status, String::from_utf8_lossy(&output.stdout), String::from_utf8_lossy(&output.stderr) ); } output.status.success() } pub fn make(host: &str) -> PathBuf { if host.contains("dragonfly") || host.contains("freebsd") || host.contains("netbsd") || host.contains("openbsd") { PathBuf::from("gmake") } else { PathBuf::from("make") } } #[track_caller] pub fn output(cmd: &mut Command) -> String { let output = match cmd.stderr(Stdio::inherit()).output() { Ok(status) => status, Err(e) => fail(&format!("failed to execute command: {cmd:?}\nerror: {e}")), }; if !output.status.success() { panic!( "command did not execute successfully: {:?}\n\ expected success, got: {}", cmd, output.status ); } String::from_utf8(output.stdout).unwrap() } pub fn output_result(cmd: &mut Command) -> Result { let output = match cmd.stderr(Stdio::inherit()).output() { Ok(status) => status, Err(e) => return Err(format!("failed to run command: {cmd:?}: {e}")), }; if !output.status.success() { return Err(format!( "command did not execute successfully: {:?}\n\ expected success, got: {}\n{}", cmd, output.status, String::from_utf8(output.stderr).map_err(|err| format!("{err:?}"))? )); } Ok(String::from_utf8(output.stdout).map_err(|err| format!("{err:?}"))?) } /// Returns the last-modified time for `path`, or zero if it doesn't exist. pub fn mtime(path: &Path) -> SystemTime { fs::metadata(path).and_then(|f| f.modified()).unwrap_or(UNIX_EPOCH) } /// Returns `true` if `dst` is up to date given that the file or files in `src` /// are used to generate it. /// /// Uses last-modified time checks to verify this. pub fn up_to_date(src: &Path, dst: &Path) -> bool { if !dst.exists() { return false; } let threshold = mtime(dst); let meta = match fs::metadata(src) { Ok(meta) => meta, Err(e) => panic!("source {src:?} failed to get metadata: {e}"), }; if meta.is_dir() { dir_up_to_date(src, threshold) } else { meta.modified().unwrap_or(UNIX_EPOCH) <= threshold } } fn dir_up_to_date(src: &Path, threshold: SystemTime) -> bool { t!(fs::read_dir(src)).map(|e| t!(e)).all(|e| { let meta = t!(e.metadata()); if meta.is_dir() { dir_up_to_date(&e.path(), threshold) } else { meta.modified().unwrap_or(UNIX_EPOCH) < threshold } }) } /// Copied from `std::path::absolute` until it stabilizes. /// /// FIXME: this shouldn't exist. pub(crate) fn absolute(path: &Path) -> PathBuf { if path.as_os_str().is_empty() { panic!("can't make empty path absolute"); } #[cfg(unix)] { t!(absolute_unix(path), format!("could not make path absolute: {}", path.display())) } #[cfg(windows)] { t!(absolute_windows(path), format!("could not make path absolute: {}", path.display())) } #[cfg(not(any(unix, windows)))] { println!("warning: bootstrap is not supported on non-unix platforms"); t!(std::fs::canonicalize(t!(std::env::current_dir()))).join(path) } } #[cfg(unix)] /// Make a POSIX path absolute without changing its semantics. fn absolute_unix(path: &Path) -> io::Result { // This is mostly a wrapper around collecting `Path::components`, with // exceptions made where this conflicts with the POSIX specification. // See 4.13 Pathname Resolution, IEEE Std 1003.1-2017 // https://pubs.opengroup.org/onlinepubs/9699919799/basedefs/V1_chap04.html#tag_04_13 use std::os::unix::prelude::OsStrExt; let mut components = path.components(); let path_os = path.as_os_str().as_bytes(); let mut normalized = if path.is_absolute() { // "If a pathname begins with two successive characters, the // first component following the leading characters may be // interpreted in an implementation-defined manner, although more than // two leading characters shall be treated as a single // character." if path_os.starts_with(b"//") && !path_os.starts_with(b"///") { components.next(); PathBuf::from("//") } else { PathBuf::new() } } else { env::current_dir()? }; normalized.extend(components); // "Interfaces using pathname resolution may specify additional constraints // when a pathname that does not name an existing directory contains at // least one non- character and contains one or more trailing // characters". // A trailing is also meaningful if "a symbolic link is // encountered during pathname resolution". if path_os.ends_with(b"/") { normalized.push(""); } Ok(normalized) } #[cfg(windows)] fn absolute_windows(path: &std::path::Path) -> std::io::Result { use std::ffi::OsString; use std::io::Error; use std::os::windows::ffi::{OsStrExt, OsStringExt}; use std::ptr::null_mut; #[link(name = "kernel32")] extern "system" { fn GetFullPathNameW( lpFileName: *const u16, nBufferLength: u32, lpBuffer: *mut u16, lpFilePart: *mut *const u16, ) -> u32; } unsafe { // encode the path as UTF-16 let path: Vec = path.as_os_str().encode_wide().chain([0]).collect(); let mut buffer = Vec::new(); // Loop until either success or failure. loop { // Try to get the absolute path let len = GetFullPathNameW( path.as_ptr(), buffer.len().try_into().unwrap(), buffer.as_mut_ptr(), null_mut(), ); match len as usize { // Failure 0 => return Err(Error::last_os_error()), // Buffer is too small, resize. len if len > buffer.len() => buffer.resize(len, 0), // Success! len => { buffer.truncate(len); return Ok(OsString::from_wide(&buffer).into()); } } } } } /// Adapted from /// /// When `clang-cl` is used with instrumentation, we need to add clang's runtime library resource /// directory to the linker flags, otherwise there will be linker errors about the profiler runtime /// missing. This function returns the path to that directory. pub fn get_clang_cl_resource_dir(clang_cl_path: &str) -> PathBuf { // Similar to how LLVM does it, to find clang's library runtime directory: // - we ask `clang-cl` to locate the `clang_rt.builtins` lib. let mut builtins_locator = Command::new(clang_cl_path); builtins_locator.args(&["/clang:-print-libgcc-file-name", "/clang:--rtlib=compiler-rt"]); let clang_rt_builtins = output(&mut builtins_locator); let clang_rt_builtins = Path::new(clang_rt_builtins.trim()); assert!( clang_rt_builtins.exists(), "`clang-cl` must correctly locate the library runtime directory" ); // - the profiler runtime will be located in the same directory as the builtins lib, like // `$LLVM_DISTRO_ROOT/lib/clang/$LLVM_VERSION/lib/windows`. let clang_rt_dir = clang_rt_builtins.parent().expect("The clang lib folder should exist"); clang_rt_dir.to_path_buf() } pub fn lld_flag_no_threads(is_windows: bool) -> &'static str { static LLD_NO_THREADS: OnceCell<(&'static str, &'static str)> = OnceCell::new(); let (windows, other) = LLD_NO_THREADS.get_or_init(|| { let out = output(Command::new("lld").arg("-flavor").arg("ld").arg("--version")); let newer = match (out.find(char::is_numeric), out.find('.')) { (Some(b), Some(e)) => out.as_str()[b..e].parse::().ok().unwrap_or(14) > 10, _ => true, }; if newer { ("/threads:1", "--threads=1") } else { ("/no-threads", "--no-threads") } }); if is_windows { windows } else { other } } pub fn dir_is_empty(dir: &Path) -> bool { t!(std::fs::read_dir(dir)).next().is_none() }