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use crate::traphandlers::{tls, wasmtime_longjmp};
use std::cell::RefCell;
use std::io;
use std::mem::{self, MaybeUninit};
use std::ptr::{self, null_mut};
/// Function which may handle custom signals while processing traps.
pub type SignalHandler<'a> =
dyn Fn(libc::c_int, *const libc::siginfo_t, *const libc::c_void) -> bool + Send + Sync + 'a;
static mut PREV_SIGSEGV: MaybeUninit<libc::sigaction> = MaybeUninit::uninit();
static mut PREV_SIGBUS: MaybeUninit<libc::sigaction> = MaybeUninit::uninit();
static mut PREV_SIGILL: MaybeUninit<libc::sigaction> = MaybeUninit::uninit();
static mut PREV_SIGFPE: MaybeUninit<libc::sigaction> = MaybeUninit::uninit();
pub unsafe fn platform_init() {
let register = |slot: &mut MaybeUninit<libc::sigaction>, signal: i32| {
let mut handler: libc::sigaction = mem::zeroed();
// The flags here are relatively careful, and they are...
//
// SA_SIGINFO gives us access to information like the program
// counter from where the fault happened.
//
// SA_ONSTACK allows us to handle signals on an alternate stack,
// so that the handler can run in response to running out of
// stack space on the main stack. Rust installs an alternate
// stack with sigaltstack, so we rely on that.
//
// SA_NODEFER allows us to reenter the signal handler if we
// crash while handling the signal, and fall through to the
// Breakpad handler by testing handlingSegFault.
handler.sa_flags = libc::SA_SIGINFO | libc::SA_NODEFER | libc::SA_ONSTACK;
handler.sa_sigaction = trap_handler as usize;
libc::sigemptyset(&mut handler.sa_mask);
if libc::sigaction(signal, &handler, slot.as_mut_ptr()) != 0 {
panic!(
"unable to install signal handler: {}",
io::Error::last_os_error(),
);
}
};
// Allow handling OOB with signals on all architectures
register(&mut PREV_SIGSEGV, libc::SIGSEGV);
// Handle `unreachable` instructions which execute `ud2` right now
register(&mut PREV_SIGILL, libc::SIGILL);
// x86 and s390x use SIGFPE to report division by zero
if cfg!(target_arch = "x86_64") || cfg!(target_arch = "s390x") {
register(&mut PREV_SIGFPE, libc::SIGFPE);
}
// Sometimes we need to handle SIGBUS too:
// - On Darwin, guard page accesses are raised as SIGBUS.
if cfg!(target_os = "macos") || cfg!(target_os = "freebsd") {
register(&mut PREV_SIGBUS, libc::SIGBUS);
}
// TODO(#1980): x86-32, if we support it, will also need a SIGFPE handler.
// TODO(#1173): ARM32, if we support it, will also need a SIGBUS handler.
}
unsafe extern "C" fn trap_handler(
signum: libc::c_int,
siginfo: *mut libc::siginfo_t,
context: *mut libc::c_void,
) {
let previous = match signum {
libc::SIGSEGV => &PREV_SIGSEGV,
libc::SIGBUS => &PREV_SIGBUS,
libc::SIGFPE => &PREV_SIGFPE,
libc::SIGILL => &PREV_SIGILL,
_ => panic!("unknown signal: {}", signum),
};
let handled = tls::with(|info| {
// If no wasm code is executing, we don't handle this as a wasm
// trap.
let info = match info {
Some(info) => info,
None => return false,
};
// If we hit an exception while handling a previous trap, that's
// quite bad, so bail out and let the system handle this
// recursive segfault.
//
// Otherwise flag ourselves as handling a trap, do the trap
// handling, and reset our trap handling flag. Then we figure
// out what to do based on the result of the trap handling.
let (pc, fp) = get_pc_and_fp(context, signum);
let jmp_buf = info.take_jmp_buf_if_trap(pc, |handler| handler(signum, siginfo, context));
// Figure out what to do based on the result of this handling of
// the trap. Note that our sentinel value of 1 means that the
// exception was handled by a custom exception handler, so we
// keep executing.
if jmp_buf.is_null() {
return false;
}
if jmp_buf as usize == 1 {
return true;
}
info.set_jit_trap(pc, fp);
// On macOS this is a bit special, unfortunately. If we were to
// `siglongjmp` out of the signal handler that notably does
// *not* reset the sigaltstack state of our signal handler. This
// seems to trick the kernel into thinking that the sigaltstack
// is still in use upon delivery of the next signal, meaning
// that the sigaltstack is not ever used again if we immediately
// call `wasmtime_longjmp` here.
//
// Note that if we use `longjmp` instead of `siglongjmp` then
// the problem is fixed. The problem with that, however, is that
// `setjmp` is much slower than `sigsetjmp` due to the
// preservation of the proceses signal mask. The reason
// `longjmp` appears to work is that it seems to call a function
// (according to published macOS sources) called
// `_sigunaltstack` which updates the kernel to say the
// sigaltstack is no longer in use. We ideally want to call that
// here but I don't think there's a stable way for us to call
// that.
//
// Given all that, on macOS only, we do the next best thing. We
// return from the signal handler after updating the register
// context. This will cause control to return to our shim
// function defined here which will perform the
// `wasmtime_longjmp` (`siglongjmp`) for us. The reason this
// works is that by returning from the signal handler we'll
// trigger all the normal machinery for "the signal handler is
// done running" which will clear the sigaltstack flag and allow
// reusing it for the next signal. Then upon resuming in our custom
// code we blow away the stack anyway with a longjmp.
if cfg!(target_os = "macos") {
unsafe extern "C" fn wasmtime_longjmp_shim(jmp_buf: *const u8) {
wasmtime_longjmp(jmp_buf)
}
set_pc(context, wasmtime_longjmp_shim as usize, jmp_buf as usize);
return true;
}
wasmtime_longjmp(jmp_buf)
});
if handled {
return;
}
// This signal is not for any compiled wasm code we expect, so we
// need to forward the signal to the next handler. If there is no
// next handler (SIG_IGN or SIG_DFL), then it's time to crash. To do
// this, we set the signal back to its original disposition and
// return. This will cause the faulting op to be re-executed which
// will crash in the normal way. If there is a next handler, call
// it. It will either crash synchronously, fix up the instruction
// so that execution can continue and return, or trigger a crash by
// returning the signal to it's original disposition and returning.
let previous = &*previous.as_ptr();
if previous.sa_flags & libc::SA_SIGINFO != 0 {
mem::transmute::<usize, extern "C" fn(libc::c_int, *mut libc::siginfo_t, *mut libc::c_void)>(
previous.sa_sigaction,
)(signum, siginfo, context)
} else if previous.sa_sigaction == libc::SIG_DFL || previous.sa_sigaction == libc::SIG_IGN {
libc::sigaction(signum, previous, ptr::null_mut());
} else {
mem::transmute::<usize, extern "C" fn(libc::c_int)>(previous.sa_sigaction)(signum)
}
}
unsafe fn get_pc_and_fp(cx: *mut libc::c_void, _signum: libc::c_int) -> (*const u8, usize) {
cfg_if::cfg_if! {
if #[cfg(all(target_os = "linux", target_arch = "x86_64"))] {
let cx = &*(cx as *const libc::ucontext_t);
(
cx.uc_mcontext.gregs[libc::REG_RIP as usize] as *const u8,
cx.uc_mcontext.gregs[libc::REG_RBP as usize] as usize
)
} else if #[cfg(all(any(target_os = "linux", target_os = "android"), target_arch = "aarch64"))] {
let cx = &*(cx as *const libc::ucontext_t);
(
cx.uc_mcontext.pc as *const u8,
cx.uc_mcontext.regs[29] as usize,
)
} else if #[cfg(all(target_os = "linux", target_arch = "s390x"))] {
// On s390x, SIGILL and SIGFPE are delivered with the PSW address
// pointing *after* the faulting instruction, while SIGSEGV and
// SIGBUS are delivered with the PSW address pointing *to* the
// faulting instruction. To handle this, the code generator registers
// any trap that results in one of "late" signals on the last byte
// of the instruction, and any trap that results in one of the "early"
// signals on the first byte of the instruction (as usual). This
// means we simply need to decrement the reported PSW address by
// one in the case of a "late" signal here to ensure we always
// correctly find the associated trap handler.
let trap_offset = match _signum {
libc::SIGILL | libc::SIGFPE => 1,
_ => 0,
};
let cx = &*(cx as *const libc::ucontext_t);
(
(cx.uc_mcontext.psw.addr - trap_offset) as *const u8,
*(cx.uc_mcontext.gregs[15] as *const usize),
)
} else if #[cfg(all(target_os = "macos", target_arch = "x86_64"))] {
let cx = &*(cx as *const libc::ucontext_t);
(
(*cx.uc_mcontext).__ss.__rip as *const u8,
(*cx.uc_mcontext).__ss.__rbp as usize,
)
} else if #[cfg(all(target_os = "macos", target_arch = "aarch64"))] {
let cx = &*(cx as *const libc::ucontext_t);
(
(*cx.uc_mcontext).__ss.__pc as *const u8,
(*cx.uc_mcontext).__ss.__fp as usize,
)
} else if #[cfg(all(target_os = "freebsd", target_arch = "x86_64"))] {
let cx = &*(cx as *const libc::ucontext_t);
(
cx.uc_mcontext.mc_rip as *const u8,
cx.uc_mcontext.mc_rbp as usize,
)
} else if #[cfg(all(target_os = "linux", target_arch = "riscv64"))] {
let cx = &*(cx as *const libc::ucontext_t);
(
cx.uc_mcontext.__gregs[libc::REG_PC] as *const u8,
cx.uc_mcontext.__gregs[libc::REG_S0] as usize,
)
}
else {
compile_error!("unsupported platform");
}
}
}
// This is only used on macOS targets for calling an unwinding shim
// function to ensure that we return from the signal handler.
//
// See more comments above where this is called for what it's doing.
unsafe fn set_pc(cx: *mut libc::c_void, pc: usize, arg1: usize) {
cfg_if::cfg_if! {
if #[cfg(not(target_os = "macos"))] {
drop((cx, pc, arg1));
unreachable!(); // not used on these platforms
} else if #[cfg(target_arch = "x86_64")] {
let cx = &mut *(cx as *mut libc::ucontext_t);
(*cx.uc_mcontext).__ss.__rip = pc as u64;
(*cx.uc_mcontext).__ss.__rdi = arg1 as u64;
// We're simulating a "pseudo-call" so we need to ensure
// stack alignment is properly respected, notably that on a
// `call` instruction the stack is 8/16-byte aligned, then
// the function adjusts itself to be 16-byte aligned.
//
// Most of the time the stack pointer is 16-byte aligned at
// the time of the trap but for more robust-ness with JIT
// code where it may ud2 in a prologue check before the
// stack is aligned we double-check here.
if (*cx.uc_mcontext).__ss.__rsp % 16 == 0 {
(*cx.uc_mcontext).__ss.__rsp -= 8;
}
} else if #[cfg(target_arch = "aarch64")] {
let cx = &mut *(cx as *mut libc::ucontext_t);
(*cx.uc_mcontext).__ss.__pc = pc as u64;
(*cx.uc_mcontext).__ss.__x[0] = arg1 as u64;
} else {
compile_error!("unsupported macos target architecture");
}
}
}
/// A function for registering a custom alternate signal stack (sigaltstack).
///
/// Rust's libstd installs an alternate stack with size `SIGSTKSZ`, which is not
/// always large enough for our signal handling code. Override it by creating
/// and registering our own alternate stack that is large enough and has a guard
/// page.
#[cold]
pub fn lazy_per_thread_init() {
// This thread local is purely used to register a `Stack` to get deallocated
// when the thread exists. Otherwise this function is only ever called at
// most once per-thread.
thread_local! {
static STACK: RefCell<Option<Stack>> = const { RefCell::new(None) };
}
/// The size of the sigaltstack (not including the guard, which will be
/// added). Make this large enough to run our signal handlers.
///
/// The main current requirement of the signal handler in terms of stack
/// space is that `malloc`/`realloc` are called to create a `Backtrace` of
/// wasm frames.
///
/// Historically this was 16k. Turns out jemalloc requires more than 16k of
/// stack space in debug mode, so this was bumped to 64k.
const MIN_STACK_SIZE: usize = 64 * 4096;
struct Stack {
mmap_ptr: *mut libc::c_void,
mmap_size: usize,
}
return STACK.with(|s| {
*s.borrow_mut() = unsafe { allocate_sigaltstack() };
});
unsafe fn allocate_sigaltstack() -> Option<Stack> {
// Check to see if the existing sigaltstack, if it exists, is big
// enough. If so we don't need to allocate our own.
let mut old_stack = mem::zeroed();
let r = libc::sigaltstack(ptr::null(), &mut old_stack);
assert_eq!(
r,
0,
"learning about sigaltstack failed: {}",
io::Error::last_os_error()
);
if old_stack.ss_flags & libc::SS_DISABLE == 0 && old_stack.ss_size >= MIN_STACK_SIZE {
return None;
}
// ... but failing that we need to allocate our own, so do all that
// here.
let page_size = crate::page_size();
let guard_size = page_size;
let alloc_size = guard_size + MIN_STACK_SIZE;
let ptr = rustix::mm::mmap_anonymous(
null_mut(),
alloc_size,
rustix::mm::ProtFlags::empty(),
rustix::mm::MapFlags::PRIVATE,
)
.expect("failed to allocate memory for sigaltstack");
// Prepare the stack with readable/writable memory and then register it
// with `sigaltstack`.
let stack_ptr = (ptr as usize + guard_size) as *mut std::ffi::c_void;
rustix::mm::mprotect(
stack_ptr,
MIN_STACK_SIZE,
rustix::mm::MprotectFlags::READ | rustix::mm::MprotectFlags::WRITE,
)
.expect("mprotect to configure memory for sigaltstack failed");
let new_stack = libc::stack_t {
ss_sp: stack_ptr,
ss_flags: 0,
ss_size: MIN_STACK_SIZE,
};
let r = libc::sigaltstack(&new_stack, ptr::null_mut());
assert_eq!(
r,
0,
"registering new sigaltstack failed: {}",
io::Error::last_os_error()
);
Some(Stack {
mmap_ptr: ptr,
mmap_size: alloc_size,
})
}
impl Drop for Stack {
fn drop(&mut self) {
unsafe {
// Deallocate the stack memory.
let r = rustix::mm::munmap(self.mmap_ptr, self.mmap_size);
debug_assert!(r.is_ok(), "munmap failed during thread shutdown");
}
}
}
}