compiler/rustc_session/src/filesearch.rs - toolchain/rustc - Git at Google

 //! A module for searching for libraries

 use smallvec::{smallvec, SmallVec};
 use std::env;
 use std::fs;
 use std::iter::FromIterator;
 use std::path::{Path, PathBuf};

 use crate::search_paths::{PathKind, SearchPath};
 use rustc_fs_util::fix_windows_verbatim_for_gcc;

 #[derive(Copy, Clone)]
 pub enum FileMatch {
     FileMatches,
     FileDoesntMatch,
 }

 #[derive(Clone)]
 pub struct FileSearch<'a> {
     sysroot: &'a Path,
     triple: &'a str,
     search_paths: &'a [SearchPath],
     tlib_path: &'a SearchPath,
     kind: PathKind,
 }

 impl<'a> FileSearch<'a> {
     pub fn search_paths(&self) -> impl Iterator<Item = &'a SearchPath> {
         let kind = self.kind;
         self.search_paths
             .iter()
             .filter(move |sp| sp.kind.matches(kind))
             .chain(std::iter::once(self.tlib_path))
     }

     pub fn get_lib_path(&self) -> PathBuf {
         make_target_lib_path(self.sysroot, self.triple)
     }

     pub fn get_self_contained_lib_path(&self) -> PathBuf {
         self.get_lib_path().join("self-contained")
     }

     pub fn new(
         sysroot: &'a Path,
         triple: &'a str,
         search_paths: &'a [SearchPath],
         tlib_path: &'a SearchPath,
         kind: PathKind,
     ) -> FileSearch<'a> {
         debug!("using sysroot = {}, triple = {}", sysroot.display(), triple);
         FileSearch { sysroot, triple, search_paths, tlib_path, kind }
     }

     /// Returns just the directories within the search paths.
     pub fn search_path_dirs(&self) -> Vec<PathBuf> {
         self.search_paths().map(|sp| sp.dir.to_path_buf()).collect()
     }
 }

 pub fn make_target_lib_path(sysroot: &Path, target_triple: &str) -> PathBuf {
     let rustlib_path = rustc_target::target_rustlib_path(sysroot, target_triple);
     PathBuf::from_iter([sysroot, Path::new(&rustlib_path), Path::new("lib")])
 }

 #[cfg(unix)]
 fn current_dll_path() -> Result<PathBuf, String> {
     use std::ffi::{CStr, OsStr};
     use std::os::unix::prelude::*;

     unsafe {
         let addr = current_dll_path as usize as *mut _;
         let mut info = std::mem::zeroed();
         if libc::dladdr(addr, &mut info) == 0 {
             return Err("dladdr failed".into());
         }
         if info.dli_fname.is_null() {
             return Err("dladdr returned null pointer".into());
         }
         let bytes = CStr::from_ptr(info.dli_fname).to_bytes();
         let os = OsStr::from_bytes(bytes);
         Ok(PathBuf::from(os))
     }
 }

 #[cfg(windows)]
 fn current_dll_path() -> Result<PathBuf, String> {
     use std::ffi::OsString;
     use std::io;
     use std::os::windows::prelude::*;
     use std::ptr;

     use winapi::um::libloaderapi::{
         GetModuleFileNameW, GetModuleHandleExW, GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS,
     };

     unsafe {
         let mut module = ptr::null_mut();
         let r = GetModuleHandleExW(
             GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS,
             current_dll_path as usize as *mut _,
             &mut module,
         );
         if r == 0 {
             return Err(format!("GetModuleHandleExW failed: {}", io::Error::last_os_error()));
         }
         let mut space = Vec::with_capacity(1024);
         let r = GetModuleFileNameW(module, space.as_mut_ptr(), space.capacity() as u32);
         if r == 0 {
             return Err(format!("GetModuleFileNameW failed: {}", io::Error::last_os_error()));
         }
         let r = r as usize;
         if r >= space.capacity() {
             return Err(format!("our buffer was too small? {}", io::Error::last_os_error()));
         }
         space.set_len(r);
         let os = OsString::from_wide(&space);
         Ok(PathBuf::from(os))
     }
 }

 pub fn sysroot_candidates() -> SmallVec<[PathBuf; 2]> {
     let target = crate::config::host_triple();
     let mut sysroot_candidates: SmallVec<[PathBuf; 2]> =
         smallvec![get_or_default_sysroot().expect("Failed finding sysroot")];
     let path = current_dll_path().and_then(|s| Ok(s.canonicalize().map_err(|e| e.to_string())?));
     if let Ok(dll) = path {
         // use `parent` twice to chop off the file name and then also the
         // directory containing the dll which should be either `lib` or `bin`.
         if let Some(path) = dll.parent().and_then(|p| p.parent()) {
             // The original `path` pointed at the `rustc_driver` crate's dll.
             // Now that dll should only be in one of two locations. The first is
             // in the compiler's libdir, for example `$sysroot/lib/*.dll`. The
             // other is the target's libdir, for example
             // `$sysroot/lib/rustlib/$target/lib/*.dll`.
             //
             // We don't know which, so let's assume that if our `path` above
             // ends in `$target` we *could* be in the target libdir, and always
             // assume that we may be in the main libdir.
             sysroot_candidates.push(path.to_owned());

             if path.ends_with(target) {
                 sysroot_candidates.extend(
                     path.parent() // chop off `$target`
                         .and_then(|p| p.parent()) // chop off `rustlib`
                         .and_then(|p| p.parent()) // chop off `lib`
                         .map(|s| s.to_owned()),
                 );
             }
         }
     }

     return sysroot_candidates;
 }

 /// This function checks if sysroot is found using env::args().next(), and if it
 /// is not found, finds sysroot from current rustc_driver dll.
 pub fn get_or_default_sysroot() -> Result<PathBuf, String> {
     // Follow symlinks.  If the resolved path is relative, make it absolute.
     fn canonicalize(path: PathBuf) -> PathBuf {
         let path = fs::canonicalize(&path).unwrap_or(path);
         // See comments on this target function, but the gist is that
         // gcc chokes on verbatim paths which fs::canonicalize generates
         // so we try to avoid those kinds of paths.
         fix_windows_verbatim_for_gcc(&path)
     }

     fn default_from_rustc_driver_dll() -> Result<PathBuf, String> {
         let dll = current_dll_path().and_then(|s| Ok(canonicalize(s)))?;

         // `dll` will be in one of the following two:
         // - compiler's libdir: $sysroot/lib/*.dll
         // - target's libdir: $sysroot/lib/rustlib/$target/lib/*.dll
         //
         // use `parent` twice to chop off the file name and then also the
         // directory containing the dll
         let dir = dll.parent().and_then(|p| p.parent()).ok_or(format!(
             "Could not move 2 levels upper using `parent()` on {}",
             dll.display()
         ))?;

         // if `dir` points target's dir, move up to the sysroot
         if dir.ends_with(crate::config::host_triple()) {
             dir.parent() // chop off `$target`
                 .and_then(|p| p.parent()) // chop off `rustlib`
                 .and_then(|p| p.parent()) // chop off `lib`
                 .map(|s| s.to_owned())
                 .ok_or(format!(
                     "Could not move 3 levels upper using `parent()` on {}",
                     dir.display()
                 ))
         } else {
             Ok(dir.to_owned())
         }
     }

     // Use env::args().next() to get the path of the executable without
     // following symlinks/canonicalizing any component. This makes the rustc
     // binary able to locate Rust libraries in systems using content-addressable
     // storage (CAS).
     fn from_env_args_next() -> Option<PathBuf> {
         match env::args_os().next() {
             Some(first_arg) => {
                 let mut p = PathBuf::from(first_arg);

                 // Check if sysroot is found using env::args().next() only if the rustc in argv[0]
                 // is a symlink (see #79253). We might want to change/remove it to conform with
                 // https://www.gnu.org/prep/standards/standards.html#Finding-Program-Files in the
                 // future.
                 if fs::read_link(&p).is_err() {
                     // Path is not a symbolic link or does not exist.
                     return None;
                 }

                 // Pop off `bin/rustc`, obtaining the suspected sysroot.
                 p.pop();
                 p.pop();
                 // Look for the target rustlib directory in the suspected sysroot.
                 let mut rustlib_path = rustc_target::target_rustlib_path(&p, "dummy");
                 rustlib_path.pop(); // pop off the dummy target.
                 if rustlib_path.exists() { Some(p) } else { None }
             }
             None => None,
         }
     }

     Ok(from_env_args_next().unwrap_or(default_from_rustc_driver_dll()?))
 }
	//! A module for searching for libraries

	use smallvec::{smallvec, SmallVec};
	use std::env;
	use std::fs;
	use std::iter::FromIterator;
	use std::path::{Path, PathBuf};

	use crate::search_paths::{PathKind, SearchPath};
	use rustc_fs_util::fix_windows_verbatim_for_gcc;

	#[derive(Copy, Clone)]
	pub enum FileMatch {
	FileMatches,
	FileDoesntMatch,
	}

	#[derive(Clone)]
	pub struct FileSearch<'a> {
	sysroot: &'a Path,
	triple: &'a str,
	search_paths: &'a [SearchPath],
	tlib_path: &'a SearchPath,
	kind: PathKind,
	}

	impl<'a> FileSearch<'a> {
	pub fn search_paths(&self) -> impl Iterator<Item = &'a SearchPath> {
	let kind = self.kind;
	self.search_paths
	.iter()
	.filter(move \|sp\| sp.kind.matches(kind))
	.chain(std::iter::once(self.tlib_path))
	}

	pub fn get_lib_path(&self) -> PathBuf {
	make_target_lib_path(self.sysroot, self.triple)
	}

	pub fn get_self_contained_lib_path(&self) -> PathBuf {
	self.get_lib_path().join("self-contained")
	}

	pub fn new(
	sysroot: &'a Path,
	triple: &'a str,
	search_paths: &'a [SearchPath],
	tlib_path: &'a SearchPath,
	kind: PathKind,
	) -> FileSearch<'a> {
	debug!("using sysroot = {}, triple = {}", sysroot.display(), triple);
	FileSearch { sysroot, triple, search_paths, tlib_path, kind }
	}

	/// Returns just the directories within the search paths.
	pub fn search_path_dirs(&self) -> Vec<PathBuf> {
	self.search_paths().map(\|sp\| sp.dir.to_path_buf()).collect()
	}
	}

	pub fn make_target_lib_path(sysroot: &Path, target_triple: &str) -> PathBuf {
	let rustlib_path = rustc_target::target_rustlib_path(sysroot, target_triple);
	PathBuf::from_iter([sysroot, Path::new(&rustlib_path), Path::new("lib")])
	}

	#[cfg(unix)]
	fn current_dll_path() -> Result<PathBuf, String> {
	use std::ffi::{CStr, OsStr};
	use std::os::unix::prelude::*;

	unsafe {
	let addr = current_dll_path as usize as *mut _;
	let mut info = std::mem::zeroed();
	if libc::dladdr(addr, &mut info) == 0 {
	return Err("dladdr failed".into());
	}
	if info.dli_fname.is_null() {
	return Err("dladdr returned null pointer".into());
	}
	let bytes = CStr::from_ptr(info.dli_fname).to_bytes();
	let os = OsStr::from_bytes(bytes);
	Ok(PathBuf::from(os))
	}
	}

	#[cfg(windows)]
	fn current_dll_path() -> Result<PathBuf, String> {
	use std::ffi::OsString;
	use std::io;
	use std::os::windows::prelude::*;
	use std::ptr;

	use winapi::um::libloaderapi::{
	GetModuleFileNameW, GetModuleHandleExW, GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS,
	};

	unsafe {
	let mut module = ptr::null_mut();
	let r = GetModuleHandleExW(
	GET_MODULE_HANDLE_EX_FLAG_FROM_ADDRESS,
	current_dll_path as usize as *mut _,
	&mut module,
	);
	if r == 0 {
	return Err(format!("GetModuleHandleExW failed: {}", io::Error::last_os_error()));
	}
	let mut space = Vec::with_capacity(1024);
	let r = GetModuleFileNameW(module, space.as_mut_ptr(), space.capacity() as u32);
	if r == 0 {
	return Err(format!("GetModuleFileNameW failed: {}", io::Error::last_os_error()));
	}
	let r = r as usize;
	if r >= space.capacity() {
	return Err(format!("our buffer was too small? {}", io::Error::last_os_error()));
	}
	space.set_len(r);
	let os = OsString::from_wide(&space);
	Ok(PathBuf::from(os))
	}
	}

	pub fn sysroot_candidates() -> SmallVec<[PathBuf; 2]> {
	let target = crate::config::host_triple();
	let mut sysroot_candidates: SmallVec<[PathBuf; 2]> =
	smallvec![get_or_default_sysroot().expect("Failed finding sysroot")];
	let path = current_dll_path().and_then(\|s\| Ok(s.canonicalize().map_err(\|e\| e.to_string())?));
	if let Ok(dll) = path {
	// use `parent` twice to chop off the file name and then also the
	// directory containing the dll which should be either `lib` or `bin`.
	if let Some(path) = dll.parent().and_then(\|p\| p.parent()) {
	// The original `path` pointed at the `rustc_driver` crate's dll.
	// Now that dll should only be in one of two locations. The first is
	// in the compiler's libdir, for example `$sysroot/lib/*.dll`. The
	// other is the target's libdir, for example
	// `$sysroot/lib/rustlib/$target/lib/*.dll`.
	//
	// We don't know which, so let's assume that if our `path` above
	// ends in `$target` we could be in the target libdir, and always
	// assume that we may be in the main libdir.
	sysroot_candidates.push(path.to_owned());

	if path.ends_with(target) {
	sysroot_candidates.extend(
	path.parent() // chop off `$target`
	.and_then(\|p\| p.parent()) // chop off `rustlib`
	.and_then(\|p\| p.parent()) // chop off `lib`
	.map(\|s\| s.to_owned()),
	);
	}
	}
	}

	return sysroot_candidates;
	}

	/// This function checks if sysroot is found using env::args().next(), and if it
	/// is not found, finds sysroot from current rustc_driver dll.
	pub fn get_or_default_sysroot() -> Result<PathBuf, String> {
	// Follow symlinks. If the resolved path is relative, make it absolute.
	fn canonicalize(path: PathBuf) -> PathBuf {
	let path = fs::canonicalize(&path).unwrap_or(path);
	// See comments on this target function, but the gist is that
	// gcc chokes on verbatim paths which fs::canonicalize generates
	// so we try to avoid those kinds of paths.
	fix_windows_verbatim_for_gcc(&path)
	}

	fn default_from_rustc_driver_dll() -> Result<PathBuf, String> {
	let dll = current_dll_path().and_then(\|s\| Ok(canonicalize(s)))?;

	// `dll` will be in one of the following two:
	// - compiler's libdir: $sysroot/lib/*.dll
	// - target's libdir: $sysroot/lib/rustlib/$target/lib/*.dll
	//
	// use `parent` twice to chop off the file name and then also the
	// directory containing the dll
	let dir = dll.parent().and_then(\|p\| p.parent()).ok_or(format!(
	"Could not move 2 levels upper using `parent()` on {}",
	dll.display()
	))?;

	// if `dir` points target's dir, move up to the sysroot
	if dir.ends_with(crate::config::host_triple()) {
	dir.parent() // chop off `$target`
	.and_then(\|p\| p.parent()) // chop off `rustlib`
	.and_then(\|p\| p.parent()) // chop off `lib`
	.map(\|s\| s.to_owned())
	.ok_or(format!(
	"Could not move 3 levels upper using `parent()` on {}",
	dir.display()
	))
	} else {
	Ok(dir.to_owned())
	}
	}

	// Use env::args().next() to get the path of the executable without
	// following symlinks/canonicalizing any component. This makes the rustc
	// binary able to locate Rust libraries in systems using content-addressable
	// storage (CAS).
	fn from_env_args_next() -> Option<PathBuf> {
	match env::args_os().next() {
	Some(first_arg) => {
	let mut p = PathBuf::from(first_arg);

	// Check if sysroot is found using env::args().next() only if the rustc in argv[0]
	// is a symlink (see #79253). We might want to change/remove it to conform with
	// https://www.gnu.org/prep/standards/standards.html#Finding-Program-Files in the
	// future.
	if fs::read_link(&p).is_err() {
	// Path is not a symbolic link or does not exist.
	return None;
	}

	// Pop off `bin/rustc`, obtaining the suspected sysroot.
	p.pop();
	p.pop();
	// Look for the target rustlib directory in the suspected sysroot.
	let mut rustlib_path = rustc_target::target_rustlib_path(&p, "dummy");
	rustlib_path.pop(); // pop off the dummy target.
	if rustlib_path.exists() { Some(p) } else { None }
	}
	None => None,
	}
	}

	Ok(from_env_args_next().unwrap_or(default_from_rustc_driver_dll()?))
	}