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

 // rsbegin.o and rsend.o are the so called "compiler runtime startup objects".
 // They contain code needed to correctly initialize the compiler runtime.
 //
 // When an executable or dylib image is linked, all user code and libraries are
 // "sandwiched" between these two object files, so code or data from rsbegin.o
 // become first in the respective sections of the image, whereas code and data
 // from rsend.o become the last ones. This effect can be used to place symbols
 // at the beginning or at the end of a section, as well as to insert any required
 // headers or footers.
 //
 // Note that the actual module entry point is located in the C runtime startup
 // object (usually called `crtX.o`), which then invokes initialization callbacks
 // of other runtime components (registered via yet another special image section).

 #![feature(no_core)]
 #![feature(lang_items)]
 #![feature(auto_traits)]
 #![crate_type = "rlib"]
 #![no_core]
 #![allow(non_camel_case_types)]

 #[lang = "sized"]
 trait Sized {}
 #[lang = "sync"]
 auto trait Sync {}
 #[lang = "copy"]
 trait Copy {}
 #[lang = "freeze"]
 auto trait Freeze {}

 #[lang = "drop_in_place"]
 #[inline]
 #[allow(unconditional_recursion)]
 pub unsafe fn drop_in_place<T: ?Sized>(to_drop: *mut T) {
     drop_in_place(to_drop);
 }

 // Frame unwind info registration
 //
 // Each module's image contains a frame unwind info section (usually
 // ".eh_frame").  When a module is loaded/unloaded into the process, the
 // unwinder must be informed about the location of this section in memory. The
 // methods of achieving that vary by the platform.  On some (e.g., Linux), the
 // unwinder can discover unwind info sections on its own (by dynamically
 // enumerating currently loaded modules via the dl_iterate_phdr() API and
 // finding their ".eh_frame" sections); Others, like Windows, require modules
 // to actively register their unwind info sections via unwinder API.
 #[cfg(all(target_os = "windows", target_arch = "x86", target_env = "gnu"))]
 pub mod eh_frames {
     #[no_mangle]
     #[link_section = ".eh_frame"]
     // Marks beginning of the stack frame unwind info section
     pub static __EH_FRAME_BEGIN__: [u8; 0] = [];

     // Scratch space for unwinder's internal book-keeping.
     // This is defined as `struct object` in $GCC/libgcc/unwind-dw2-fde.h.
     static mut OBJ: [isize; 6] = [0; 6];

     macro_rules! impl_copy {
         ($($t:ty)*) => {
             $(
                 impl ::Copy for $t {}
             )*
         }
     }

     impl_copy! {
         usize u8 u16 u32 u64 u128
         isize i8 i16 i32 i64 i128
         f32 f64
         bool char
     }

     // Unwind info registration/deregistration routines.
     extern "C" {
         fn __register_frame_info(eh_frame_begin: *const u8, object: *mut u8);
         fn __deregister_frame_info(eh_frame_begin: *const u8, object: *mut u8);
     }

     unsafe extern "C" fn init() {
         // register unwind info on module startup
         __register_frame_info(&__EH_FRAME_BEGIN__ as *const u8, &mut OBJ as *mut _ as *mut u8);
     }

     unsafe extern "C" fn uninit() {
         // unregister on shutdown
         __deregister_frame_info(&__EH_FRAME_BEGIN__ as *const u8, &mut OBJ as *mut _ as *mut u8);
     }

     // MinGW-specific init/uninit routine registration
     pub mod mingw_init {
         // MinGW's startup objects (crt0.o / dllcrt0.o) will invoke global constructors in the
         // .ctors and .dtors sections on startup and exit. In the case of DLLs, this is done when
         // the DLL is loaded and unloaded.
         //
         // The linker will sort the sections, which ensures that our callbacks are located at the
         // end of the list. Since constructors are run in reverse order, this ensures that our
         // callbacks are the first and last ones executed.

         #[link_section = ".ctors.65535"] // .ctors.* : C initialization callbacks
         pub static P_INIT: unsafe extern "C" fn() = super::init;

         #[link_section = ".dtors.65535"] // .dtors.* : C termination callbacks
         pub static P_UNINIT: unsafe extern "C" fn() = super::uninit;
     }
 }
	// rsbegin.o and rsend.o are the so called "compiler runtime startup objects".
	// They contain code needed to correctly initialize the compiler runtime.
	//
	// When an executable or dylib image is linked, all user code and libraries are
	// "sandwiched" between these two object files, so code or data from rsbegin.o
	// become first in the respective sections of the image, whereas code and data
	// from rsend.o become the last ones. This effect can be used to place symbols
	// at the beginning or at the end of a section, as well as to insert any required
	// headers or footers.
	//
	// Note that the actual module entry point is located in the C runtime startup
	// object (usually called `crtX.o`), which then invokes initialization callbacks
	// of other runtime components (registered via yet another special image section).

	#![feature(no_core)]
	#![feature(lang_items)]
	#![feature(auto_traits)]
	#![crate_type = "rlib"]
	#![no_core]
	#![allow(non_camel_case_types)]

	#[lang = "sized"]
	trait Sized {}
	#[lang = "sync"]
	auto trait Sync {}
	#[lang = "copy"]
	trait Copy {}
	#[lang = "freeze"]
	auto trait Freeze {}

	#[lang = "drop_in_place"]
	#[inline]
	#[allow(unconditional_recursion)]
	pub unsafe fn drop_in_place<T: ?Sized>(to_drop: *mut T) {
	drop_in_place(to_drop);
	}

	// Frame unwind info registration
	//
	// Each module's image contains a frame unwind info section (usually
	// ".eh_frame"). When a module is loaded/unloaded into the process, the
	// unwinder must be informed about the location of this section in memory. The
	// methods of achieving that vary by the platform. On some (e.g., Linux), the
	// unwinder can discover unwind info sections on its own (by dynamically
	// enumerating currently loaded modules via the dl_iterate_phdr() API and
	// finding their ".eh_frame" sections); Others, like Windows, require modules
	// to actively register their unwind info sections via unwinder API.
	#[cfg(all(target_os = "windows", target_arch = "x86", target_env = "gnu"))]
	pub mod eh_frames {
	#[no_mangle]
	#[link_section = ".eh_frame"]
	// Marks beginning of the stack frame unwind info section
	pub static __EH_FRAME_BEGIN__: [u8; 0] = [];

	// Scratch space for unwinder's internal book-keeping.
	// This is defined as `struct object` in $GCC/libgcc/unwind-dw2-fde.h.
	static mut OBJ: [isize; 6] = [0; 6];

	macro_rules! impl_copy {
	($($t:ty)*) => {
	$(
	impl ::Copy for $t {}
	)*
	}
	}

	impl_copy! {
	usize u8 u16 u32 u64 u128
	isize i8 i16 i32 i64 i128
	f32 f64
	bool char
	}

	// Unwind info registration/deregistration routines.
	extern "C" {
	fn __register_frame_info(eh_frame_begin: const u8, object: mut u8);
	fn __deregister_frame_info(eh_frame_begin: const u8, object: mut u8);
	}

	unsafe extern "C" fn init() {
	// register unwind info on module startup
	__register_frame_info(&__EH_FRAME_BEGIN__ as const u8, &mut OBJ as mut _ as *mut u8);
	}

	unsafe extern "C" fn uninit() {
	// unregister on shutdown
	__deregister_frame_info(&__EH_FRAME_BEGIN__ as const u8, &mut OBJ as mut _ as *mut u8);
	}

	// MinGW-specific init/uninit routine registration
	pub mod mingw_init {
	// MinGW's startup objects (crt0.o / dllcrt0.o) will invoke global constructors in the
	// .ctors and .dtors sections on startup and exit. In the case of DLLs, this is done when
	// the DLL is loaded and unloaded.
	//
	// The linker will sort the sections, which ensures that our callbacks are located at the
	// end of the list. Since constructors are run in reverse order, this ensures that our
	// callbacks are the first and last ones executed.

	#[link_section = ".ctors.65535"] // .ctors.* : C initialization callbacks
	pub static P_INIT: unsafe extern "C" fn() = super::init;

	#[link_section = ".dtors.65535"] // .dtors.* : C termination callbacks
	pub static P_UNINIT: unsafe extern "C" fn() = super::uninit;
	}
	}