src/libstd/sys/unix/stack_overflow.rs - third_party/rust - Git at Google

 #![cfg_attr(test, allow(dead_code))]

 use self::imp::{make_handler, drop_handler};

 pub use self::imp::cleanup;
 pub use self::imp::init;

 pub struct Handler {
     _data: *mut libc::c_void
 }

 impl Handler {
     pub unsafe fn new() -> Handler {
         make_handler()
     }
 }

 impl Drop for Handler {
     fn drop(&mut self) {
         unsafe {
             drop_handler(self);
         }
     }
 }

 #[cfg(any(target_os = "linux",
           target_os = "macos",
           target_os = "bitrig",
           target_os = "dragonfly",
           target_os = "freebsd",
           target_os = "solaris",
           all(target_os = "netbsd", not(target_vendor = "rumprun")),
           target_os = "openbsd"))]
 mod imp {
     use super::Handler;
     use crate::mem;
     use crate::ptr;

     use libc::{sigaltstack, SIGSTKSZ, SS_DISABLE};
     use libc::{sigaction, SIGBUS, SIG_DFL,
                SA_SIGINFO, SA_ONSTACK, sighandler_t};
     use libc::{mmap, munmap};
     use libc::{SIGSEGV, PROT_READ, PROT_WRITE, MAP_PRIVATE, MAP_ANON};
     use libc::MAP_FAILED;

     use crate::sys_common::thread_info;


     #[cfg(any(target_os = "linux", target_os = "android"))]
     unsafe fn siginfo_si_addr(info: *mut libc::siginfo_t) -> usize {
         #[repr(C)]
         struct siginfo_t {
             a: [libc::c_int; 3], // si_signo, si_errno, si_code
             si_addr: *mut libc::c_void,
         }

         (*(info as *const siginfo_t)).si_addr as usize
     }

     #[cfg(not(any(target_os = "linux", target_os = "android")))]
     unsafe fn siginfo_si_addr(info: *mut libc::siginfo_t) -> usize {
         (*info).si_addr as usize
     }

     // Signal handler for the SIGSEGV and SIGBUS handlers. We've got guard pages
     // (unmapped pages) at the end of every thread's stack, so if a thread ends
     // up running into the guard page it'll trigger this handler. We want to
     // detect these cases and print out a helpful error saying that the stack
     // has overflowed. All other signals, however, should go back to what they
     // were originally supposed to do.
     //
     // This handler currently exists purely to print an informative message
     // whenever a thread overflows its stack. We then abort to exit and
     // indicate a crash, but to avoid a misleading SIGSEGV that might lead
     // users to believe that unsafe code has accessed an invalid pointer; the
     // SIGSEGV encountered when overflowing the stack is expected and
     // well-defined.
     //
     // If this is not a stack overflow, the handler un-registers itself and
     // then returns (to allow the original signal to be delivered again).
     // Returning from this kind of signal handler is technically not defined
     // to work when reading the POSIX spec strictly, but in practice it turns
     // out many large systems and all implementations allow returning from a
     // signal handler to work. For a more detailed explanation see the
     // comments on #26458.
     unsafe extern fn signal_handler(signum: libc::c_int,
                                     info: *mut libc::siginfo_t,
                                     _data: *mut libc::c_void) {
         use crate::sys_common::util::report_overflow;

         let guard = thread_info::stack_guard().unwrap_or(0..0);
         let addr = siginfo_si_addr(info);

         // If the faulting address is within the guard page, then we print a
         // message saying so and abort.
         if guard.start <= addr && addr < guard.end {
             report_overflow();
             rtabort!("stack overflow");
         } else {
             // Unregister ourselves by reverting back to the default behavior.
             let mut action: sigaction = mem::zeroed();
             action.sa_sigaction = SIG_DFL;
             sigaction(signum, &action, ptr::null_mut());

             // See comment above for why this function returns.
         }
     }

     static mut MAIN_ALTSTACK: *mut libc::c_void = ptr::null_mut();

     pub unsafe fn init() {
         let mut action: sigaction = mem::zeroed();
         action.sa_flags = SA_SIGINFO | SA_ONSTACK;
         action.sa_sigaction = signal_handler as sighandler_t;
         sigaction(SIGSEGV, &action, ptr::null_mut());
         sigaction(SIGBUS, &action, ptr::null_mut());

         let handler = make_handler();
         MAIN_ALTSTACK = handler._data;
         mem::forget(handler);
     }

     pub unsafe fn cleanup() {
         Handler { _data: MAIN_ALTSTACK };
     }

     unsafe fn get_stackp() -> *mut libc::c_void {
         let stackp = mmap(ptr::null_mut(),
                           SIGSTKSZ,
                           PROT_READ | PROT_WRITE,
                           MAP_PRIVATE | MAP_ANON,
                           -1,
                           0);
         if stackp == MAP_FAILED {
             panic!("failed to allocate an alternative stack");
         }
         stackp
     }

     #[cfg(any(target_os = "linux",
               target_os = "macos",
               target_os = "bitrig",
               target_os = "freebsd",
               target_os = "netbsd",
               target_os = "openbsd",
               target_os = "solaris"))]
     unsafe fn get_stack() -> libc::stack_t {
         libc::stack_t { ss_sp: get_stackp(), ss_flags: 0, ss_size: SIGSTKSZ }
     }

     #[cfg(target_os = "dragonfly")]
     unsafe fn get_stack() -> libc::stack_t {
         libc::stack_t { ss_sp: get_stackp() as *mut i8, ss_flags: 0, ss_size: SIGSTKSZ }
     }

     pub unsafe fn make_handler() -> Handler {
         let mut stack = mem::zeroed();
         sigaltstack(ptr::null(), &mut stack);
         // Configure alternate signal stack, if one is not already set.
         if stack.ss_flags & SS_DISABLE != 0 {
             stack = get_stack();
             sigaltstack(&stack, ptr::null_mut());
             Handler { _data: stack.ss_sp as *mut libc::c_void }
         } else {
             Handler { _data: ptr::null_mut() }
         }
     }

     pub unsafe fn drop_handler(handler: &mut Handler) {
         if !handler._data.is_null() {
             let stack =  libc::stack_t {
                 ss_sp: ptr::null_mut(),
                 ss_flags: SS_DISABLE,
                 // Workaround for bug in macOS implementation of sigaltstack
                 // UNIX2003 which returns ENOMEM when disabling a stack while
                 // passing ss_size smaller than MINSIGSTKSZ. According to POSIX
                 // both ss_sp and ss_size should be ignored in this case.
                 ss_size: SIGSTKSZ,
             };
             sigaltstack(&stack, ptr::null_mut());
             munmap(handler._data, SIGSTKSZ);
         }
     }
 }

 #[cfg(not(any(target_os = "linux",
               target_os = "macos",
               target_os = "bitrig",
               target_os = "dragonfly",
               target_os = "freebsd",
               target_os = "solaris",
               all(target_os = "netbsd", not(target_vendor = "rumprun")),
               target_os = "openbsd")))]
 mod imp {
     use crate::ptr;

     pub unsafe fn init() {
     }

     pub unsafe fn cleanup() {
     }

     pub unsafe fn make_handler() -> super::Handler {
         super::Handler { _data: ptr::null_mut() }
     }

     pub unsafe fn drop_handler(_handler: &mut super::Handler) {
     }
 }
	#![cfg_attr(test, allow(dead_code))]

	use self::imp::{make_handler, drop_handler};

	pub use self::imp::cleanup;
	pub use self::imp::init;

	pub struct Handler {
	_data: *mut libc::c_void
	}

	impl Handler {
	pub unsafe fn new() -> Handler {
	make_handler()
	}
	}

	impl Drop for Handler {
	fn drop(&mut self) {
	unsafe {
	drop_handler(self);
	}
	}
	}

	#[cfg(any(target_os = "linux",
	target_os = "macos",
	target_os = "bitrig",
	target_os = "dragonfly",
	target_os = "freebsd",
	target_os = "solaris",
	all(target_os = "netbsd", not(target_vendor = "rumprun")),
	target_os = "openbsd"))]
	mod imp {
	use super::Handler;
	use crate::mem;
	use crate::ptr;

	use libc::{sigaltstack, SIGSTKSZ, SS_DISABLE};
	use libc::{sigaction, SIGBUS, SIG_DFL,
	SA_SIGINFO, SA_ONSTACK, sighandler_t};
	use libc::{mmap, munmap};
	use libc::{SIGSEGV, PROT_READ, PROT_WRITE, MAP_PRIVATE, MAP_ANON};
	use libc::MAP_FAILED;

	use crate::sys_common::thread_info;


	#[cfg(any(target_os = "linux", target_os = "android"))]
	unsafe fn siginfo_si_addr(info: *mut libc::siginfo_t) -> usize {
	#[repr(C)]
	struct siginfo_t {
	a: [libc::c_int; 3], // si_signo, si_errno, si_code
	si_addr: *mut libc::c_void,
	}

	((info as const siginfo_t)).si_addr as usize
	}

	#[cfg(not(any(target_os = "linux", target_os = "android")))]
	unsafe fn siginfo_si_addr(info: *mut libc::siginfo_t) -> usize {
	(*info).si_addr as usize
	}

	// Signal handler for the SIGSEGV and SIGBUS handlers. We've got guard pages
	// (unmapped pages) at the end of every thread's stack, so if a thread ends
	// up running into the guard page it'll trigger this handler. We want to
	// detect these cases and print out a helpful error saying that the stack
	// has overflowed. All other signals, however, should go back to what they
	// were originally supposed to do.
	//
	// This handler currently exists purely to print an informative message
	// whenever a thread overflows its stack. We then abort to exit and
	// indicate a crash, but to avoid a misleading SIGSEGV that might lead
	// users to believe that unsafe code has accessed an invalid pointer; the
	// SIGSEGV encountered when overflowing the stack is expected and
	// well-defined.
	//
	// If this is not a stack overflow, the handler un-registers itself and
	// then returns (to allow the original signal to be delivered again).
	// Returning from this kind of signal handler is technically not defined
	// to work when reading the POSIX spec strictly, but in practice it turns
	// out many large systems and all implementations allow returning from a
	// signal handler to work. For a more detailed explanation see the
	// comments on #26458.
	unsafe extern fn signal_handler(signum: libc::c_int,
	info: *mut libc::siginfo_t,
	_data: *mut libc::c_void) {
	use crate::sys_common::util::report_overflow;

	let guard = thread_info::stack_guard().unwrap_or(0..0);
	let addr = siginfo_si_addr(info);

	// If the faulting address is within the guard page, then we print a
	// message saying so and abort.
	if guard.start <= addr && addr < guard.end {
	report_overflow();
	rtabort!("stack overflow");
	} else {
	// Unregister ourselves by reverting back to the default behavior.
	let mut action: sigaction = mem::zeroed();
	action.sa_sigaction = SIG_DFL;
	sigaction(signum, &action, ptr::null_mut());

	// See comment above for why this function returns.
	}
	}

	static mut MAIN_ALTSTACK: *mut libc::c_void = ptr::null_mut();

	pub unsafe fn init() {
	let mut action: sigaction = mem::zeroed();
	action.sa_flags = SA_SIGINFO \| SA_ONSTACK;
	action.sa_sigaction = signal_handler as sighandler_t;
	sigaction(SIGSEGV, &action, ptr::null_mut());
	sigaction(SIGBUS, &action, ptr::null_mut());

	let handler = make_handler();
	MAIN_ALTSTACK = handler._data;
	mem::forget(handler);
	}

	pub unsafe fn cleanup() {
	Handler { _data: MAIN_ALTSTACK };
	}

	unsafe fn get_stackp() -> *mut libc::c_void {
	let stackp = mmap(ptr::null_mut(),
	SIGSTKSZ,
	PROT_READ \| PROT_WRITE,
	MAP_PRIVATE \| MAP_ANON,
	-1,
	0);
	if stackp == MAP_FAILED {
	panic!("failed to allocate an alternative stack");
	}
	stackp
	}

	#[cfg(any(target_os = "linux",
	target_os = "macos",
	target_os = "bitrig",
	target_os = "freebsd",
	target_os = "netbsd",
	target_os = "openbsd",
	target_os = "solaris"))]
	unsafe fn get_stack() -> libc::stack_t {
	libc::stack_t { ss_sp: get_stackp(), ss_flags: 0, ss_size: SIGSTKSZ }
	}

	#[cfg(target_os = "dragonfly")]
	unsafe fn get_stack() -> libc::stack_t {
	libc::stack_t { ss_sp: get_stackp() as *mut i8, ss_flags: 0, ss_size: SIGSTKSZ }
	}

	pub unsafe fn make_handler() -> Handler {
	let mut stack = mem::zeroed();
	sigaltstack(ptr::null(), &mut stack);
	// Configure alternate signal stack, if one is not already set.
	if stack.ss_flags & SS_DISABLE != 0 {
	stack = get_stack();
	sigaltstack(&stack, ptr::null_mut());
	Handler { _data: stack.ss_sp as *mut libc::c_void }
	} else {
	Handler { _data: ptr::null_mut() }
	}
	}

	pub unsafe fn drop_handler(handler: &mut Handler) {
	if !handler._data.is_null() {
	let stack = libc::stack_t {
	ss_sp: ptr::null_mut(),
	ss_flags: SS_DISABLE,
	// Workaround for bug in macOS implementation of sigaltstack
	// UNIX2003 which returns ENOMEM when disabling a stack while
	// passing ss_size smaller than MINSIGSTKSZ. According to POSIX
	// both ss_sp and ss_size should be ignored in this case.
	ss_size: SIGSTKSZ,
	};
	sigaltstack(&stack, ptr::null_mut());
	munmap(handler._data, SIGSTKSZ);
	}
	}
	}

	#[cfg(not(any(target_os = "linux",
	target_os = "macos",
	target_os = "bitrig",
	target_os = "dragonfly",
	target_os = "freebsd",
	target_os = "solaris",
	all(target_os = "netbsd", not(target_vendor = "rumprun")),
	target_os = "openbsd")))]
	mod imp {
	use crate::ptr;

	pub unsafe fn init() {
	}

	pub unsafe fn cleanup() {
	}

	pub unsafe fn make_handler() -> super::Handler {
	super::Handler { _data: ptr::null_mut() }
	}

	pub unsafe fn drop_handler(_handler: &mut super::Handler) {
	}
	}