crates/libloading/src/os/unix/mod.rs - platform/external/rust/android-crates-io - Git at Google

 // A hack for docs.rs to build documentation that has both windows and linux documentation in the
 // same rustdoc build visible.
 #[cfg(all(libloading_docs, not(unix)))]
 mod unix_imports {}
 #[cfg(any(not(libloading_docs), unix))]
 mod unix_imports {
     pub(super) use std::os::unix::ffi::OsStrExt;
 }

 pub use self::consts::*;
 use self::unix_imports::*;
 use std::ffi::{CStr, OsStr};
 use std::os::raw;
 use std::{fmt, marker, mem, ptr};
 use util::{cstr_cow_from_bytes, ensure_compatible_types};

 mod consts;

 /// Run code and handle errors reported by `dlerror`.
 ///
 /// This function first executes the `closure` function containing calls to the functions that
 /// report their errors via `dlerror`. This closure may return either `None` or `Some(*)` to
 /// further affect operation of this function.
 ///
 /// In case the `closure` returns `None`, `with_dlerror` inspects the `dlerror`. `dlerror` may
 /// decide to not provide any error description, in which case `Err(None)` is returned to the
 /// caller. Otherwise the `error` callback is invoked to allow inspection and conversion of the
 /// error message. The conversion result is returned as `Err(Some(Error))`.
 ///
 /// If the operations that report their errors via `dlerror` were all successful, `closure` should
 /// return `Some(T)` instead. In this case `dlerror` is not inspected at all.
 ///
 /// # Notes
 ///
 /// The whole `dlerror` handling scheme is done via setting and querying some global state. For
 /// that reason it is not safe to use dynamic library loading in MT-capable environment at all.
 /// Only in POSIX 2008+TC1 a thread-local state was allowed for `dlerror`, making the dl* family of
 /// functions possibly MT-safe, depending on the implementation of `dlerror`.
 ///
 /// In practice (as of 2020-04-01) most of the widely used targets use a thread-local for error
 /// state and have been doing so for a long time.
 pub fn with_dlerror<T, F, Error>(closure: F, error: fn(&CStr) -> Error) -> Result<T, Option<Error>>
 where
     F: FnOnce() -> Option<T>,
 {
     // We used to guard all uses of dl* functions with our own mutex. This made them safe to use in
     // MT programs provided the only way a program used dl* was via this library. However, it also
     // had a number of downsides or cases where it failed to handle the problems. For instance,
     // if any other library called `dlerror` internally concurrently with `libloading` things would
     // still go awry.
     //
     // On platforms where `dlerror` is still MT-unsafe, `dlsym` (`Library::get`) can spuriously
     // succeed and return a null pointer for a symbol when the actual symbol look-up operation
     // fails. Instances where the actual symbol _could_ be `NULL` are platform specific. For
     // instance on GNU glibc based-systems (an excerpt from dlsym(3)):
     //
     // > The value of a symbol returned by dlsym() will never be NULL if the shared object is the
     // > result of normal compilation,  since  a  global  symbol is never placed at the NULL
     // > address. There are nevertheless cases where a lookup using dlsym() may return NULL as the
     // > value of a symbol. For example, the symbol value may be  the  result of a GNU indirect
     // > function (IFUNC) resolver function that returns NULL as the resolved value.

     // While we could could call `dlerror` here to clear the previous error value, only the `dlsym`
     // call depends on it being cleared beforehand and only in some cases too. We will instead
     // clear the error inside the dlsym binding instead.
     //
     // In all the other cases, clearing the error here will only be hiding misuse of these bindings
     // or a bug in implementation of dl* family of functions.
     closure().ok_or_else(|| unsafe {
         // This code will only get executed if the `closure` returns `None`.
         let dlerror_str = dlerror();
         if dlerror_str.is_null() {
             // In non-dlsym case this may happen when there’re bugs in our bindings or there’s
             // non-libloading user of libdl; possibly in another thread.
             None
         } else {
             // You can’t even rely on error string being static here; call to subsequent dlerror
             // may invalidate or overwrite the error message. Why couldn’t they simply give up the
             // ownership over the message?
             // TODO: should do locale-aware conversion here. OTOH Rust doesn’t seem to work well in
             // any system that uses non-utf8 locale, so I doubt there’s a problem here.
             Some(error(CStr::from_ptr(dlerror_str)))
             // Since we do a copy of the error string above, maybe we should call dlerror again to
             // let libdl know it may free its copy of the string now?
         }
     })
 }

 /// A platform-specific counterpart of the cross-platform [`Library`](crate::Library).
 pub struct Library {
     handle: *mut raw::c_void,
 }

 unsafe impl Send for Library {}

 // That being said... this section in the volume 2 of POSIX.1-2008 states:
 //
 // > All functions defined by this volume of POSIX.1-2008 shall be thread-safe, except that the
 // > following functions need not be thread-safe.
 //
 // With notable absence of any dl* function other than dlerror in the list. By “this volume”
 // I suppose they refer precisely to the “volume 2”. dl* family of functions are specified
 // by this same volume, so the conclusion is indeed that dl* functions are required by POSIX
 // to be thread-safe. Great!
 //
 // See for more details:
 //
 //  * https://github.com/nagisa/rust_libloading/pull/17
 //  * http://pubs.opengroup.org/onlinepubs/9699919799/functions/V2_chap02.html#tag_15_09_01
 unsafe impl Sync for Library {}

 impl Library {
     /// Find and eagerly load a shared library (module).
     ///
     /// If the `filename` contains a [path separator], the `filename` is interpreted as a `path` to
     /// a file. Otherwise, platform-specific algorithms are employed to find a library with a
     /// matching file name.
     ///
     /// This is equivalent to <code>[Library::open](filename, [RTLD_LAZY] | [RTLD_LOCAL])</code>.
     ///
     /// [path separator]: std::path::MAIN_SEPARATOR
     ///
     /// # Safety
     ///
     /// When a library is loaded, initialisation routines contained within the library are executed.
     /// For the purposes of safety, the execution of these routines is conceptually the same calling an
     /// unknown foreign function and may impose arbitrary requirements on the caller for the call
     /// to be sound.
     ///
     /// Additionally, the callers of this function must also ensure that execution of the
     /// termination routines contained within the library is safe as well. These routines may be
     /// executed when the library is unloaded.
     #[inline]
     pub unsafe fn new<P: AsRef<OsStr>>(filename: P) -> Result<Library, crate::Error> {
         Library::open(Some(filename), RTLD_LAZY | RTLD_LOCAL)
     }

     /// Load the `Library` representing the current executable.
     ///
     /// [`Library::get`] calls of the returned `Library` will look for symbols in following
     /// locations in order:
     ///
     /// 1. The original program image;
     /// 2. Any executable object files (e.g. shared libraries) loaded at program startup;
     /// 3. Any executable object files loaded at runtime (e.g. via other `Library::new` calls or via
     ///    calls to the `dlopen` function).
     ///
     /// Note that the behaviour of a `Library` loaded with this method is different from that of
     /// Libraries loaded with [`os::windows::Library::this`].
     ///
     /// This is equivalent to <code>[Library::open](None, [RTLD_LAZY] | [RTLD_LOCAL])</code>.
     ///
     /// [`os::windows::Library::this`]: crate::os::windows::Library::this
     #[inline]
     pub fn this() -> Library {
         unsafe {
             // SAFE: this does not load any new shared library images, no danger in it executing
             // initialiser routines.
             Library::open(None::<&OsStr>, RTLD_LAZY | RTLD_LOCAL).expect("this should never fail")
         }
     }

     /// Find and load an executable object file (shared library).
     ///
     /// See documentation for [`Library::this`] for further description of the behaviour
     /// when the `filename` is `None`. Otherwise see [`Library::new`].
     ///
     /// Corresponds to `dlopen(filename, flags)`.
     ///
     /// # Safety
     ///
     /// When a library is loaded, initialisation routines contained within the library are executed.
     /// For the purposes of safety, the execution of these routines is conceptually the same calling an
     /// unknown foreign function and may impose arbitrary requirements on the caller for the call
     /// to be sound.
     ///
     /// Additionally, the callers of this function must also ensure that execution of the
     /// termination routines contained within the library is safe as well. These routines may be
     /// executed when the library is unloaded.
     pub unsafe fn open<P>(filename: Option<P>, flags: raw::c_int) -> Result<Library, crate::Error>
     where
         P: AsRef<OsStr>,
     {
         let filename = match filename {
             None => None,
             Some(ref f) => Some(cstr_cow_from_bytes(f.as_ref().as_bytes())?),
         };
         with_dlerror(
             move || {
                 let result = dlopen(
                     match filename {
                         None => ptr::null(),
                         Some(ref f) => f.as_ptr(),
                     },
                     flags,
                 );
                 // ensure filename lives until dlopen completes
                 drop(filename);
                 if result.is_null() {
                     None
                 } else {
                     Some(Library { handle: result })
                 }
             },
             |desc| crate::Error::DlOpen { desc: desc.into() },
         )
         .map_err(|e| e.unwrap_or(crate::Error::DlOpenUnknown))
     }

     unsafe fn get_impl<T, F>(&self, symbol: &[u8], on_null: F) -> Result<Symbol<T>, crate::Error>
     where
         F: FnOnce() -> Result<Symbol<T>, crate::Error>,
     {
         ensure_compatible_types::<T, *mut raw::c_void>()?;
         let symbol = cstr_cow_from_bytes(symbol)?;
         // `dlsym` may return nullptr in two cases: when a symbol genuinely points to a null
         // pointer or the symbol cannot be found. In order to detect this case a double dlerror
         // pattern must be used, which is, sadly, a little bit racy.
         //
         // We try to leave as little space as possible for this to occur, but we can’t exactly
         // fully prevent it.
         let result = with_dlerror(
             || {
                 dlerror();
                 let symbol = dlsym(self.handle, symbol.as_ptr());
                 if symbol.is_null() {
                     None
                 } else {
                     Some(Symbol {
                         pointer: symbol,
                         pd: marker::PhantomData,
                     })
                 }
             },
             |desc| crate::Error::DlSym { desc: desc.into() },
         );
         match result {
             Err(None) => on_null(),
             Err(Some(e)) => Err(e),
             Ok(x) => Ok(x),
         }
     }

     /// Get a pointer to a function or static variable by symbol name.
     ///
     /// The `symbol` may not contain any null bytes, with the exception of the last byte. Providing a
     /// null terminated `symbol` may help to avoid an allocation.
     ///
     /// Symbol is interpreted as-is; no mangling is done. This means that symbols like `x::y` are
     /// most likely invalid.
     ///
     /// # Safety
     ///
     /// Users of this API must specify the correct type of the function or variable loaded. Using a
     /// `Symbol` with a wrong type is undefined.
     ///
     /// # Platform-specific behaviour
     ///
     /// Implementation of thread local variables is extremely platform specific and uses of such
     /// variables that work on e.g. Linux may have unintended behaviour on other targets.
     ///
     /// On POSIX implementations where the `dlerror` function is not confirmed to be MT-safe (such
     /// as FreeBSD), this function will unconditionally return an error when the underlying `dlsym`
     /// call returns a null pointer. There are rare situations where `dlsym` returns a genuine null
     /// pointer without it being an error. If loading a null pointer is something you care about,
     /// consider using the [`Library::get_singlethreaded`] call.
     #[inline(always)]
     pub unsafe fn get<T>(&self, symbol: &[u8]) -> Result<Symbol<T>, crate::Error> {
         extern crate cfg_if;
         cfg_if::cfg_if! {
             // These targets are known to have MT-safe `dlerror`.
             if #[cfg(any(
                 target_os = "linux",
                 target_os = "android",
                 target_os = "openbsd",
                 target_os = "macos",
                 target_os = "ios",
                 target_os = "solaris",
                 target_os = "illumos",
                 target_os = "redox",
                 target_os = "fuchsia"
             ))] {
                 self.get_singlethreaded(symbol)
             } else {
                 self.get_impl(symbol, || Err(crate::Error::DlSymUnknown))
             }
         }
     }

     /// Get a pointer to function or static variable by symbol name.
     ///
     /// The `symbol` may not contain any null bytes, with the exception of the last byte. Providing a
     /// null terminated `symbol` may help to avoid an allocation.
     ///
     /// Symbol is interpreted as-is; no mangling is done. This means that symbols like `x::y` are
     /// most likely invalid.
     ///
     /// # Safety
     ///
     /// Users of this API must specify the correct type of the function or variable loaded.
     ///
     /// It is up to the user of this library to ensure that no other calls to an MT-unsafe
     /// implementation of `dlerror` occur during the execution of this function. Failing that, the
     /// behaviour of this function is not defined.
     ///
     /// # Platform-specific behaviour
     ///
     /// The implementation of thread-local variables is extremely platform specific and uses of such
     /// variables that work on e.g. Linux may have unintended behaviour on other targets.
     #[inline(always)]
     pub unsafe fn get_singlethreaded<T>(&self, symbol: &[u8]) -> Result<Symbol<T>, crate::Error> {
         self.get_impl(symbol, || {
             Ok(Symbol {
                 pointer: ptr::null_mut(),
                 pd: marker::PhantomData,
             })
         })
     }

     /// Convert the `Library` to a raw handle.
     ///
     /// The handle returned by this function shall be usable with APIs which accept handles
     /// as returned by `dlopen`.
     pub fn into_raw(self) -> *mut raw::c_void {
         let handle = self.handle;
         mem::forget(self);
         handle
     }

     /// Convert a raw handle returned by `dlopen`-family of calls to a `Library`.
     ///
     /// # Safety
     ///
     /// The pointer shall be a result of a successful call of the `dlopen`-family of functions or a
     /// pointer previously returned by `Library::into_raw` call. It must be valid to call `dlclose`
     /// with this pointer as an argument.
     pub unsafe fn from_raw(handle: *mut raw::c_void) -> Library {
         Library { handle }
     }

     /// Unload the library.
     ///
     /// This method might be a no-op, depending on the flags with which the `Library` was opened,
     /// what library was opened or other platform specifics.
     ///
     /// You only need to call this if you are interested in handling any errors that may arise when
     /// library is unloaded. Otherwise the implementation of `Drop` for `Library` will close the
     /// library and ignore the errors were they arise.
     ///
     /// The underlying data structures may still get leaked if an error does occur.
     pub fn close(self) -> Result<(), crate::Error> {
         let result = with_dlerror(
             || {
                 if unsafe { dlclose(self.handle) } == 0 {
                     Some(())
                 } else {
                     None
                 }
             },
             |desc| crate::Error::DlClose { desc: desc.into() },
         )
         .map_err(|e| e.unwrap_or(crate::Error::DlCloseUnknown));
         // While the library is not free'd yet in case of an error, there is no reason to try
         // dropping it again, because all that will do is try calling `dlclose` again. only
         // this time it would ignore the return result, which we already seen failing…
         std::mem::forget(self);
         result
     }
 }

 impl Drop for Library {
     fn drop(&mut self) {
         unsafe {
             dlclose(self.handle);
         }
     }
 }

 impl fmt::Debug for Library {
     fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
         f.write_str(&format!("Library@{:p}", self.handle))
     }
 }

 /// Symbol from a library.
 ///
 /// A major difference compared to the cross-platform `Symbol` is that this does not ensure that the
 /// `Symbol` does not outlive the `Library` it comes from.
 pub struct Symbol<T> {
     pointer: *mut raw::c_void,
     pd: marker::PhantomData<T>,
 }

 impl<T> Symbol<T> {
     /// Convert the loaded `Symbol` into a raw pointer.
     pub fn into_raw(self) -> *mut raw::c_void {
         self.pointer
     }

     /// Convert the loaded `Symbol` into a raw pointer.
     /// For unix this does the same as into_raw.
     pub fn as_raw_ptr(self) -> *mut raw::c_void {
         self.pointer
     }
 }

 impl<T> Symbol<Option<T>> {
     /// Lift Option out of the symbol.
     pub fn lift_option(self) -> Option<Symbol<T>> {
         if self.pointer.is_null() {
             None
         } else {
             Some(Symbol {
                 pointer: self.pointer,
                 pd: marker::PhantomData,
             })
         }
     }
 }

 unsafe impl<T: Send> Send for Symbol<T> {}
 unsafe impl<T: Sync> Sync for Symbol<T> {}

 impl<T> Clone for Symbol<T> {
     fn clone(&self) -> Symbol<T> {
         Symbol { ..*self }
     }
 }

 impl<T> ::std::ops::Deref for Symbol<T> {
     type Target = T;
     fn deref(&self) -> &T {
         unsafe {
             // Additional reference level for a dereference on `deref` return value.
             &*(&self.pointer as *const *mut _ as *const T)
         }
     }
 }

 impl<T> fmt::Debug for Symbol<T> {
     fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
         unsafe {
             let mut info = mem::MaybeUninit::<DlInfo>::uninit();
             if dladdr(self.pointer, info.as_mut_ptr()) != 0 {
                 let info = info.assume_init();
                 if info.dli_sname.is_null() {
                     f.write_str(&format!(
                         "Symbol@{:p} from {:?}",
                         self.pointer,
                         CStr::from_ptr(info.dli_fname)
                     ))
                 } else {
                     f.write_str(&format!(
                         "Symbol {:?}@{:p} from {:?}",
                         CStr::from_ptr(info.dli_sname),
                         self.pointer,
                         CStr::from_ptr(info.dli_fname)
                     ))
                 }
             } else {
                 f.write_str(&format!("Symbol@{:p}", self.pointer))
             }
         }
     }
 }

 // Platform specific things
 #[cfg_attr(any(target_os = "linux", target_os = "android"), link(name = "dl"))]
 #[cfg_attr(any(target_os = "freebsd", target_os = "dragonfly"), link(name = "c"))]
 extern "C" {
     fn dlopen(filename: *const raw::c_char, flags: raw::c_int) -> *mut raw::c_void;
     fn dlclose(handle: *mut raw::c_void) -> raw::c_int;
     fn dlsym(handle: *mut raw::c_void, symbol: *const raw::c_char) -> *mut raw::c_void;
     fn dlerror() -> *mut raw::c_char;
     fn dladdr(addr: *mut raw::c_void, info: *mut DlInfo) -> raw::c_int;
 }

 #[repr(C)]
 struct DlInfo {
     dli_fname: *const raw::c_char,
     dli_fbase: *mut raw::c_void,
     dli_sname: *const raw::c_char,
     dli_saddr: *mut raw::c_void,
 }
	// A hack for docs.rs to build documentation that has both windows and linux documentation in the
	// same rustdoc build visible.
	#[cfg(all(libloading_docs, not(unix)))]
	mod unix_imports {}
	#[cfg(any(not(libloading_docs), unix))]
	mod unix_imports {
	pub(super) use std::os::unix::ffi::OsStrExt;
	}

	pub use self::consts::*;
	use self::unix_imports::*;
	use std::ffi::{CStr, OsStr};
	use std::os::raw;
	use std::{fmt, marker, mem, ptr};
	use util::{cstr_cow_from_bytes, ensure_compatible_types};

	mod consts;

	/// Run code and handle errors reported by `dlerror`.
	///
	/// This function first executes the `closure` function containing calls to the functions that
	/// report their errors via `dlerror`. This closure may return either `None` or `Some(*)` to
	/// further affect operation of this function.
	///
	/// In case the `closure` returns `None`, `with_dlerror` inspects the `dlerror`. `dlerror` may
	/// decide to not provide any error description, in which case `Err(None)` is returned to the
	/// caller. Otherwise the `error` callback is invoked to allow inspection and conversion of the
	/// error message. The conversion result is returned as `Err(Some(Error))`.
	///
	/// If the operations that report their errors via `dlerror` were all successful, `closure` should
	/// return `Some(T)` instead. In this case `dlerror` is not inspected at all.
	///
	/// # Notes
	///
	/// The whole `dlerror` handling scheme is done via setting and querying some global state. For
	/// that reason it is not safe to use dynamic library loading in MT-capable environment at all.
	/// Only in POSIX 2008+TC1 a thread-local state was allowed for `dlerror`, making the dl* family of
	/// functions possibly MT-safe, depending on the implementation of `dlerror`.
	///
	/// In practice (as of 2020-04-01) most of the widely used targets use a thread-local for error
	/// state and have been doing so for a long time.
	pub fn with_dlerror<T, F, Error>(closure: F, error: fn(&CStr) -> Error) -> Result<T, Option<Error>>
	where
	F: FnOnce() -> Option<T>,
	{
	// We used to guard all uses of dl* functions with our own mutex. This made them safe to use in
	// MT programs provided the only way a program used dl* was via this library. However, it also
	// had a number of downsides or cases where it failed to handle the problems. For instance,
	// if any other library called `dlerror` internally concurrently with `libloading` things would
	// still go awry.
	//
	// On platforms where `dlerror` is still MT-unsafe, `dlsym` (`Library::get`) can spuriously
	// succeed and return a null pointer for a symbol when the actual symbol look-up operation
	// fails. Instances where the actual symbol _could_ be `NULL` are platform specific. For
	// instance on GNU glibc based-systems (an excerpt from dlsym(3)):
	//
	// > The value of a symbol returned by dlsym() will never be NULL if the shared object is the
	// > result of normal compilation, since a global symbol is never placed at the NULL
	// > address. There are nevertheless cases where a lookup using dlsym() may return NULL as the
	// > value of a symbol. For example, the symbol value may be the result of a GNU indirect
	// > function (IFUNC) resolver function that returns NULL as the resolved value.

	// While we could could call `dlerror` here to clear the previous error value, only the `dlsym`
	// call depends on it being cleared beforehand and only in some cases too. We will instead
	// clear the error inside the dlsym binding instead.
	//
	// In all the other cases, clearing the error here will only be hiding misuse of these bindings
	// or a bug in implementation of dl* family of functions.
	closure().ok_or_else(\|\| unsafe {
	// This code will only get executed if the `closure` returns `None`.
	let dlerror_str = dlerror();
	if dlerror_str.is_null() {
	// In non-dlsym case this may happen when there’re bugs in our bindings or there’s
	// non-libloading user of libdl; possibly in another thread.
	None
	} else {
	// You can’t even rely on error string being static here; call to subsequent dlerror
	// may invalidate or overwrite the error message. Why couldn’t they simply give up the
	// ownership over the message?
	// TODO: should do locale-aware conversion here. OTOH Rust doesn’t seem to work well in
	// any system that uses non-utf8 locale, so I doubt there’s a problem here.
	Some(error(CStr::from_ptr(dlerror_str)))
	// Since we do a copy of the error string above, maybe we should call dlerror again to
	// let libdl know it may free its copy of the string now?
	}
	})
	}

	/// A platform-specific counterpart of the cross-platform [`Library`](crate::Library).
	pub struct Library {
	handle: *mut raw::c_void,
	}

	unsafe impl Send for Library {}

	// That being said... this section in the volume 2 of POSIX.1-2008 states:
	//
	// > All functions defined by this volume of POSIX.1-2008 shall be thread-safe, except that the
	// > following functions need not be thread-safe.
	//
	// With notable absence of any dl* function other than dlerror in the list. By “this volume”
	// I suppose they refer precisely to the “volume 2”. dl* family of functions are specified
	// by this same volume, so the conclusion is indeed that dl* functions are required by POSIX
	// to be thread-safe. Great!
	//
	// See for more details:
	//
	// * https://github.com/nagisa/rust_libloading/pull/17
	// * http://pubs.opengroup.org/onlinepubs/9699919799/functions/V2_chap02.html#tag_15_09_01
	unsafe impl Sync for Library {}

	impl Library {
	/// Find and eagerly load a shared library (module).
	///
	/// If the `filename` contains a [path separator], the `filename` is interpreted as a `path` to
	/// a file. Otherwise, platform-specific algorithms are employed to find a library with a
	/// matching file name.
	///
	/// This is equivalent to <code>[Library::open](filename, [RTLD_LAZY] \| [RTLD_LOCAL])</code>.
	///
	/// [path separator]: std::path::MAIN_SEPARATOR
	///
	/// # Safety
	///
	/// When a library is loaded, initialisation routines contained within the library are executed.
	/// For the purposes of safety, the execution of these routines is conceptually the same calling an
	/// unknown foreign function and may impose arbitrary requirements on the caller for the call
	/// to be sound.
	///
	/// Additionally, the callers of this function must also ensure that execution of the
	/// termination routines contained within the library is safe as well. These routines may be
	/// executed when the library is unloaded.
	#[inline]
	pub unsafe fn new<P: AsRef<OsStr>>(filename: P) -> Result<Library, crate::Error> {
	Library::open(Some(filename), RTLD_LAZY \| RTLD_LOCAL)
	}

	/// Load the `Library` representing the current executable.
	///
	/// [`Library::get`] calls of the returned `Library` will look for symbols in following
	/// locations in order:
	///
	/// 1. The original program image;
	/// 2. Any executable object files (e.g. shared libraries) loaded at program startup;
	/// 3. Any executable object files loaded at runtime (e.g. via other `Library::new` calls or via
	/// calls to the `dlopen` function).
	///
	/// Note that the behaviour of a `Library` loaded with this method is different from that of
	/// Libraries loaded with [`os::windows::Library::this`].
	///
	/// This is equivalent to <code>[Library::open](None, [RTLD_LAZY] \| [RTLD_LOCAL])</code>.
	///
	/// [`os::windows::Library::this`]: crate::os::windows::Library::this
	#[inline]
	pub fn this() -> Library {
	unsafe {
	// SAFE: this does not load any new shared library images, no danger in it executing
	// initialiser routines.
	Library::open(None::<&OsStr>, RTLD_LAZY \| RTLD_LOCAL).expect("this should never fail")
	}
	}

	/// Find and load an executable object file (shared library).
	///
	/// See documentation for [`Library::this`] for further description of the behaviour
	/// when the `filename` is `None`. Otherwise see [`Library::new`].
	///
	/// Corresponds to `dlopen(filename, flags)`.
	///
	/// # Safety
	///
	/// When a library is loaded, initialisation routines contained within the library are executed.
	/// For the purposes of safety, the execution of these routines is conceptually the same calling an
	/// unknown foreign function and may impose arbitrary requirements on the caller for the call
	/// to be sound.
	///
	/// Additionally, the callers of this function must also ensure that execution of the
	/// termination routines contained within the library is safe as well. These routines may be
	/// executed when the library is unloaded.
	pub unsafe fn open<P>(filename: Option<P>, flags: raw::c_int) -> Result<Library, crate::Error>
	where
	P: AsRef<OsStr>,
	{
	let filename = match filename {
	None => None,
	Some(ref f) => Some(cstr_cow_from_bytes(f.as_ref().as_bytes())?),
	};
	with_dlerror(
	move \|\| {
	let result = dlopen(
	match filename {
	None => ptr::null(),
	Some(ref f) => f.as_ptr(),
	},
	flags,
	);
	// ensure filename lives until dlopen completes
	drop(filename);
	if result.is_null() {
	None
	} else {
	Some(Library { handle: result })
	}
	},
	\|desc\| crate::Error::DlOpen { desc: desc.into() },
	)
	.map_err(\|e\| e.unwrap_or(crate::Error::DlOpenUnknown))
	}

	unsafe fn get_impl<T, F>(&self, symbol: &[u8], on_null: F) -> Result<Symbol<T>, crate::Error>
	where
	F: FnOnce() -> Result<Symbol<T>, crate::Error>,
	{
	ensure_compatible_types::<T, *mut raw::c_void>()?;
	let symbol = cstr_cow_from_bytes(symbol)?;
	// `dlsym` may return nullptr in two cases: when a symbol genuinely points to a null
	// pointer or the symbol cannot be found. In order to detect this case a double dlerror
	// pattern must be used, which is, sadly, a little bit racy.
	//
	// We try to leave as little space as possible for this to occur, but we can’t exactly
	// fully prevent it.
	let result = with_dlerror(
	\|\| {
	dlerror();
	let symbol = dlsym(self.handle, symbol.as_ptr());
	if symbol.is_null() {
	None
	} else {
	Some(Symbol {
	pointer: symbol,
	pd: marker::PhantomData,
	})
	}
	},
	\|desc\| crate::Error::DlSym { desc: desc.into() },
	);
	match result {
	Err(None) => on_null(),
	Err(Some(e)) => Err(e),
	Ok(x) => Ok(x),
	}
	}

	/// Get a pointer to a function or static variable by symbol name.
	///
	/// The `symbol` may not contain any null bytes, with the exception of the last byte. Providing a
	/// null terminated `symbol` may help to avoid an allocation.
	///
	/// Symbol is interpreted as-is; no mangling is done. This means that symbols like `x::y` are
	/// most likely invalid.
	///
	/// # Safety
	///
	/// Users of this API must specify the correct type of the function or variable loaded. Using a
	/// `Symbol` with a wrong type is undefined.
	///
	/// # Platform-specific behaviour
	///
	/// Implementation of thread local variables is extremely platform specific and uses of such
	/// variables that work on e.g. Linux may have unintended behaviour on other targets.
	///
	/// On POSIX implementations where the `dlerror` function is not confirmed to be MT-safe (such
	/// as FreeBSD), this function will unconditionally return an error when the underlying `dlsym`
	/// call returns a null pointer. There are rare situations where `dlsym` returns a genuine null
	/// pointer without it being an error. If loading a null pointer is something you care about,
	/// consider using the [`Library::get_singlethreaded`] call.
	#[inline(always)]
	pub unsafe fn get<T>(&self, symbol: &[u8]) -> Result<Symbol<T>, crate::Error> {
	extern crate cfg_if;
	cfg_if::cfg_if! {
	// These targets are known to have MT-safe `dlerror`.
	if #[cfg(any(
	target_os = "linux",
	target_os = "android",
	target_os = "openbsd",
	target_os = "macos",
	target_os = "ios",
	target_os = "solaris",
	target_os = "illumos",
	target_os = "redox",
	target_os = "fuchsia"
	))] {
	self.get_singlethreaded(symbol)
	} else {
	self.get_impl(symbol, \|\| Err(crate::Error::DlSymUnknown))
	}
	}
	}

	/// Get a pointer to function or static variable by symbol name.
	///
	/// The `symbol` may not contain any null bytes, with the exception of the last byte. Providing a
	/// null terminated `symbol` may help to avoid an allocation.
	///
	/// Symbol is interpreted as-is; no mangling is done. This means that symbols like `x::y` are
	/// most likely invalid.
	///
	/// # Safety
	///
	/// Users of this API must specify the correct type of the function or variable loaded.
	///
	/// It is up to the user of this library to ensure that no other calls to an MT-unsafe
	/// implementation of `dlerror` occur during the execution of this function. Failing that, the
	/// behaviour of this function is not defined.
	///
	/// # Platform-specific behaviour
	///
	/// The implementation of thread-local variables is extremely platform specific and uses of such
	/// variables that work on e.g. Linux may have unintended behaviour on other targets.
	#[inline(always)]
	pub unsafe fn get_singlethreaded<T>(&self, symbol: &[u8]) -> Result<Symbol<T>, crate::Error> {
	self.get_impl(symbol, \|\| {
	Ok(Symbol {
	pointer: ptr::null_mut(),
	pd: marker::PhantomData,
	})
	})
	}

	/// Convert the `Library` to a raw handle.
	///
	/// The handle returned by this function shall be usable with APIs which accept handles
	/// as returned by `dlopen`.
	pub fn into_raw(self) -> *mut raw::c_void {
	let handle = self.handle;
	mem::forget(self);
	handle
	}

	/// Convert a raw handle returned by `dlopen`-family of calls to a `Library`.
	///
	/// # Safety
	///
	/// The pointer shall be a result of a successful call of the `dlopen`-family of functions or a
	/// pointer previously returned by `Library::into_raw` call. It must be valid to call `dlclose`
	/// with this pointer as an argument.
	pub unsafe fn from_raw(handle: *mut raw::c_void) -> Library {
	Library { handle }
	}

	/// Unload the library.
	///
	/// This method might be a no-op, depending on the flags with which the `Library` was opened,
	/// what library was opened or other platform specifics.
	///
	/// You only need to call this if you are interested in handling any errors that may arise when
	/// library is unloaded. Otherwise the implementation of `Drop` for `Library` will close the
	/// library and ignore the errors were they arise.
	///
	/// The underlying data structures may still get leaked if an error does occur.
	pub fn close(self) -> Result<(), crate::Error> {
	let result = with_dlerror(
	\|\| {
	if unsafe { dlclose(self.handle) } == 0 {
	Some(())
	} else {
	None
	}
	},
	\|desc\| crate::Error::DlClose { desc: desc.into() },
	)
	.map_err(\|e\| e.unwrap_or(crate::Error::DlCloseUnknown));
	// While the library is not free'd yet in case of an error, there is no reason to try
	// dropping it again, because all that will do is try calling `dlclose` again. only
	// this time it would ignore the return result, which we already seen failing…
	std::mem::forget(self);
	result
	}
	}

	impl Drop for Library {
	fn drop(&mut self) {
	unsafe {
	dlclose(self.handle);
	}
	}
	}

	impl fmt::Debug for Library {
	fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
	f.write_str(&format!("Library@{:p}", self.handle))
	}
	}

	/// Symbol from a library.
	///
	/// A major difference compared to the cross-platform `Symbol` is that this does not ensure that the
	/// `Symbol` does not outlive the `Library` it comes from.
	pub struct Symbol<T> {
	pointer: *mut raw::c_void,
	pd: marker::PhantomData<T>,
	}

	impl<T> Symbol<T> {
	/// Convert the loaded `Symbol` into a raw pointer.
	pub fn into_raw(self) -> *mut raw::c_void {
	self.pointer
	}

	/// Convert the loaded `Symbol` into a raw pointer.
	/// For unix this does the same as into_raw.
	pub fn as_raw_ptr(self) -> *mut raw::c_void {
	self.pointer
	}
	}

	impl<T> Symbol<Option<T>> {
	/// Lift Option out of the symbol.
	pub fn lift_option(self) -> Option<Symbol<T>> {
	if self.pointer.is_null() {
	None
	} else {
	Some(Symbol {
	pointer: self.pointer,
	pd: marker::PhantomData,
	})
	}
	}
	}

	unsafe impl<T: Send> Send for Symbol<T> {}
	unsafe impl<T: Sync> Sync for Symbol<T> {}

	impl<T> Clone for Symbol<T> {
	fn clone(&self) -> Symbol<T> {
	Symbol { ..*self }
	}
	}

	impl<T> ::std::ops::Deref for Symbol<T> {
	type Target = T;
	fn deref(&self) -> &T {
	unsafe {
	// Additional reference level for a dereference on `deref` return value.
	&(&self.pointer as const mut _ as const T)
	}
	}
	}

	impl<T> fmt::Debug for Symbol<T> {
	fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
	unsafe {
	let mut info = mem::MaybeUninit::<DlInfo>::uninit();
	if dladdr(self.pointer, info.as_mut_ptr()) != 0 {
	let info = info.assume_init();
	if info.dli_sname.is_null() {
	f.write_str(&format!(
	"Symbol@{:p} from {:?}",
	self.pointer,
	CStr::from_ptr(info.dli_fname)
	))
	} else {
	f.write_str(&format!(
	"Symbol {:?}@{:p} from {:?}",
	CStr::from_ptr(info.dli_sname),
	self.pointer,
	CStr::from_ptr(info.dli_fname)
	))
	}
	} else {
	f.write_str(&format!("Symbol@{:p}", self.pointer))
	}
	}
	}
	}

	// Platform specific things
	#[cfg_attr(any(target_os = "linux", target_os = "android"), link(name = "dl"))]
	#[cfg_attr(any(target_os = "freebsd", target_os = "dragonfly"), link(name = "c"))]
	extern "C" {
	fn dlopen(filename: const raw::c_char, flags: raw::c_int) -> mut raw::c_void;
	fn dlclose(handle: *mut raw::c_void) -> raw::c_int;
	fn dlsym(handle: mut raw::c_void, symbol: const raw::c_char) -> *mut raw::c_void;
	fn dlerror() -> *mut raw::c_char;
	fn dladdr(addr: mut raw::c_void, info: mut DlInfo) -> raw::c_int;
	}

	#[repr(C)]
	struct DlInfo {
	dli_fname: *const raw::c_char,
	dli_fbase: *mut raw::c_void,
	dli_sname: *const raw::c_char,
	dli_saddr: *mut raw::c_void,
	}