armv7a/usr/lib/rustlib/src/rust/library/panic_unwind/src/emcc.rs - manifest_repos/toolchain - Git at Google

 //! Unwinding for *emscripten* target.
 //!
 //! Whereas Rust's usual unwinding implementation for Unix platforms
 //! calls into the libunwind APIs directly, on Emscripten we instead
 //! call into the C++ unwinding APIs. This is just an expedience since
 //! Emscripten's runtime always implements those APIs and does not
 //! implement libunwind.

 use alloc::boxed::Box;
 use core::any::Any;
 use core::intrinsics;
 use core::mem;
 use core::ptr;
 use core::sync::atomic::{AtomicBool, Ordering};
 use unwind as uw;

 // This matches the layout of std::type_info in C++
 #[repr(C)]
 struct TypeInfo {
     vtable: *const usize,
     name: *const u8,
 }
 unsafe impl Sync for TypeInfo {}

 extern "C" {
     // The leading `\x01` byte here is actually a magical signal to LLVM to
     // *not* apply any other mangling like prefixing with a `_` character.
     //
     // This symbol is the vtable used by C++'s `std::type_info`. Objects of type
     // `std::type_info`, type descriptors, have a pointer to this table. Type
     // descriptors are referenced by the C++ EH structures defined above and
     // that we construct below.
     //
     // Note that the real size is larger than 3 usize, but we only need our
     // vtable to point to the third element.
     #[link_name = "\x01_ZTVN10__cxxabiv117__class_type_infoE"]
     static CLASS_TYPE_INFO_VTABLE: [usize; 3];
 }

 // std::type_info for a rust_panic class
 #[lang = "eh_catch_typeinfo"]
 static EXCEPTION_TYPE_INFO: TypeInfo = TypeInfo {
     // Normally we would use .as_ptr().add(2) but this doesn't work in a const context.
     vtable: unsafe { &CLASS_TYPE_INFO_VTABLE[2] },
     // This intentionally doesn't use the normal name mangling scheme because
     // we don't want C++ to be able to produce or catch Rust panics.
     name: b"rust_panic\0".as_ptr(),
 };

 // NOTE(nbdd0121): The `canary` field will be part of stable ABI after `c_unwind` stabilization.
 #[repr(C)]
 struct Exception {
     // See `gcc.rs` on why this is present. We already have a static here so just use it.
     canary: *const TypeInfo,

     // This is necessary because C++ code can capture our exception with
     // std::exception_ptr and rethrow it multiple times, possibly even in
     // another thread.
     caught: AtomicBool,

     // This needs to be an Option because the object's lifetime follows C++
     // semantics: when catch_unwind moves the Box out of the exception it must
     // still leave the exception object in a valid state because its destructor
     // is still going to be called by __cxa_end_catch.
     data: Option<Box<dyn Any + Send>>,
 }

 pub unsafe fn cleanup(ptr: *mut u8) -> Box<dyn Any + Send> {
     // intrinsics::try actually gives us a pointer to this structure.
     #[repr(C)]
     struct CatchData {
         ptr: *mut u8,
         is_rust_panic: bool,
     }
     let catch_data = &*(ptr as *mut CatchData);

     let adjusted_ptr = __cxa_begin_catch(catch_data.ptr as *mut libc::c_void) as *mut Exception;
     if !catch_data.is_rust_panic {
         super::__rust_foreign_exception();
     }

     let canary = ptr::addr_of!((*adjusted_ptr).canary).read();
     if !ptr::eq(canary, &EXCEPTION_TYPE_INFO) {
         super::__rust_foreign_exception();
     }

     let was_caught = (*adjusted_ptr).caught.swap(true, Ordering::SeqCst);
     if was_caught {
         // Since cleanup() isn't allowed to panic, we just abort instead.
         intrinsics::abort();
     }
     let out = (*adjusted_ptr).data.take().unwrap();
     __cxa_end_catch();
     out
 }

 pub unsafe fn panic(data: Box<dyn Any + Send>) -> u32 {
     let exception = __cxa_allocate_exception(mem::size_of::<Exception>()) as *mut Exception;
     if exception.is_null() {
         return uw::_URC_FATAL_PHASE1_ERROR as u32;
     }
     ptr::write(
         exception,
         Exception {
             canary: &EXCEPTION_TYPE_INFO,
             caught: AtomicBool::new(false),
             data: Some(data),
         },
     );
     __cxa_throw(exception as *mut _, &EXCEPTION_TYPE_INFO, exception_cleanup);
 }

 extern "C" fn exception_cleanup(ptr: *mut libc::c_void) -> *mut libc::c_void {
     unsafe {
         if let Some(b) = (ptr as *mut Exception).read().data {
             drop(b);
             super::__rust_drop_panic();
         }
         ptr
     }
 }

 extern "C" {
     fn __cxa_allocate_exception(thrown_size: libc::size_t) -> *mut libc::c_void;
     fn __cxa_begin_catch(thrown_exception: *mut libc::c_void) -> *mut libc::c_void;
     fn __cxa_end_catch();
     fn __cxa_throw(
         thrown_exception: *mut libc::c_void,
         tinfo: *const TypeInfo,
         dest: extern "C" fn(*mut libc::c_void) -> *mut libc::c_void,
     ) -> !;
 }
	//! Unwinding for emscripten target.
	//!
	//! Whereas Rust's usual unwinding implementation for Unix platforms
	//! calls into the libunwind APIs directly, on Emscripten we instead
	//! call into the C++ unwinding APIs. This is just an expedience since
	//! Emscripten's runtime always implements those APIs and does not
	//! implement libunwind.

	use alloc::boxed::Box;
	use core::any::Any;
	use core::intrinsics;
	use core::mem;
	use core::ptr;
	use core::sync::atomic::{AtomicBool, Ordering};
	use unwind as uw;

	// This matches the layout of std::type_info in C++
	#[repr(C)]
	struct TypeInfo {
	vtable: *const usize,
	name: *const u8,
	}
	unsafe impl Sync for TypeInfo {}

	extern "C" {
	// The leading `\x01` byte here is actually a magical signal to LLVM to
	// not apply any other mangling like prefixing with a `_` character.
	//
	// This symbol is the vtable used by C++'s `std::type_info`. Objects of type
	// `std::type_info`, type descriptors, have a pointer to this table. Type
	// descriptors are referenced by the C++ EH structures defined above and
	// that we construct below.
	//
	// Note that the real size is larger than 3 usize, but we only need our
	// vtable to point to the third element.
	#[link_name = "\x01_ZTVN10__cxxabiv117__class_type_infoE"]
	static CLASS_TYPE_INFO_VTABLE: [usize; 3];
	}

	// std::type_info for a rust_panic class
	#[lang = "eh_catch_typeinfo"]
	static EXCEPTION_TYPE_INFO: TypeInfo = TypeInfo {
	// Normally we would use .as_ptr().add(2) but this doesn't work in a const context.
	vtable: unsafe { &CLASS_TYPE_INFO_VTABLE[2] },
	// This intentionally doesn't use the normal name mangling scheme because
	// we don't want C++ to be able to produce or catch Rust panics.
	name: b"rust_panic\0".as_ptr(),
	};

	// NOTE(nbdd0121): The `canary` field will be part of stable ABI after `c_unwind` stabilization.
	#[repr(C)]
	struct Exception {
	// See `gcc.rs` on why this is present. We already have a static here so just use it.
	canary: *const TypeInfo,

	// This is necessary because C++ code can capture our exception with
	// std::exception_ptr and rethrow it multiple times, possibly even in
	// another thread.
	caught: AtomicBool,

	// This needs to be an Option because the object's lifetime follows C++
	// semantics: when catch_unwind moves the Box out of the exception it must
	// still leave the exception object in a valid state because its destructor
	// is still going to be called by __cxa_end_catch.
	data: Option<Box<dyn Any + Send>>,
	}

	pub unsafe fn cleanup(ptr: *mut u8) -> Box<dyn Any + Send> {
	// intrinsics::try actually gives us a pointer to this structure.
	#[repr(C)]
	struct CatchData {
	ptr: *mut u8,
	is_rust_panic: bool,
	}
	let catch_data = &(ptr as mut CatchData);

	let adjusted_ptr = __cxa_begin_catch(catch_data.ptr as mut libc::c_void) as mut Exception;
	if !catch_data.is_rust_panic {
	super::__rust_foreign_exception();
	}

	let canary = ptr::addr_of!((*adjusted_ptr).canary).read();
	if !ptr::eq(canary, &EXCEPTION_TYPE_INFO) {
	super::__rust_foreign_exception();
	}

	let was_caught = (*adjusted_ptr).caught.swap(true, Ordering::SeqCst);
	if was_caught {
	// Since cleanup() isn't allowed to panic, we just abort instead.
	intrinsics::abort();
	}
	let out = (*adjusted_ptr).data.take().unwrap();
	__cxa_end_catch();
	out
	}

	pub unsafe fn panic(data: Box<dyn Any + Send>) -> u32 {
	let exception = __cxa_allocate_exception(mem::size_of::<Exception>()) as *mut Exception;
	if exception.is_null() {
	return uw::_URC_FATAL_PHASE1_ERROR as u32;
	}
	ptr::write(
	exception,
	Exception {
	canary: &EXCEPTION_TYPE_INFO,
	caught: AtomicBool::new(false),
	data: Some(data),
	},
	);
	__cxa_throw(exception as *mut _, &EXCEPTION_TYPE_INFO, exception_cleanup);
	}

	extern "C" fn exception_cleanup(ptr: mut libc::c_void) -> mut libc::c_void {
	unsafe {
	if let Some(b) = (ptr as *mut Exception).read().data {
	drop(b);
	super::__rust_drop_panic();
	}
	ptr
	}
	}

	extern "C" {
	fn __cxa_allocate_exception(thrown_size: libc::size_t) -> *mut libc::c_void;
	fn __cxa_begin_catch(thrown_exception: mut libc::c_void) -> mut libc::c_void;
	fn __cxa_end_catch();
	fn __cxa_throw(
	thrown_exception: *mut libc::c_void,
	tinfo: *const TypeInfo,
	dest: extern "C" fn(mut libc::c_void) -> mut libc::c_void,
	) -> !;
	}