cosmopolitan/libc/calls/sig.c

/*-*- mode:c;indent-tabs-mode:nil;c-basic-offset:2;tab-width:8;coding:utf-8 -*-│
│ vi: set et ft=c ts=2 sts=2 sw=2 fenc=utf-8                               :vi │
╞══════════════════════════════════════════════════════════════════════════════╡
│ Copyright 2022 Justine Alexandra Roberts Tunney                              │
│                                                                              │
│ Permission to use, copy, modify, and/or distribute this software for         │
│ any purpose with or without fee is hereby granted, provided that the         │
│ above copyright notice and this permission notice appear in all copies.      │
│                                                                              │
│ THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL                │
│ WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED                │
│ WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE             │
│ AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL         │
│ DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR        │
│ PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER               │
│ TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR             │
│ PERFORMANCE OF THIS SOFTWARE.                                                │
╚─────────────────────────────────────────────────────────────────────────────*/
#include "libc/sysv/consts/sig.h"
#include "ape/sections.internal.h"
#include "libc/calls/calls.h"
#include "libc/calls/sig.internal.h"
#include "libc/calls/state.internal.h"
#include "libc/calls/struct/sigaction.h"
#include "libc/calls/struct/siginfo.h"
#include "libc/calls/struct/sigset.internal.h"
#include "libc/calls/struct/ucontext.internal.h"
#include "libc/calls/ucontext.h"
#include "libc/dce.h"
#include "libc/errno.h"
#include "libc/intrin/atomic.h"
#include "libc/intrin/bsf.h"
#include "libc/intrin/describebacktrace.internal.h"
#include "libc/intrin/dll.h"
#include "libc/intrin/strace.internal.h"
#include "libc/nt/console.h"
#include "libc/nt/enum/context.h"
#include "libc/nt/enum/exceptionhandleractions.h"
#include "libc/nt/enum/signal.h"
#include "libc/nt/enum/status.h"
#include "libc/nt/runtime.h"
#include "libc/nt/signals.h"
#include "libc/nt/struct/ntexceptionpointers.h"
#include "libc/nt/synchronization.h"
#include "libc/nt/thread.h"
#include "libc/str/str.h"
#include "libc/sysv/consts/sa.h"
#include "libc/sysv/consts/sicode.h"
#include "libc/sysv/consts/ss.h"
#include "libc/thread/posixthread.internal.h"
#ifdef __x86_64__

/**
 * @fileoverview Cosmopolitan Signals for Windows.
 */

struct SignalFrame {
  unsigned rva;
  unsigned flags;
  siginfo_t si;
  ucontext_t ctx;
};

static textwindows bool __sig_ignored_by_default(int sig) {
  return sig == SIGURG ||   //
         sig == SIGCONT ||  //
         sig == SIGCHLD ||  //
         sig == SIGWINCH;
}

textwindows bool __sig_ignored(int sig) {
  return __sighandrvas[sig] == (intptr_t)SIG_IGN ||
         (__sighandrvas[sig] == (intptr_t)SIG_DFL &&
          __sig_ignored_by_default(sig));
}

textwindows void __sig_delete(int sig) {
  struct Dll *e;
  atomic_fetch_and_explicit(&__sig.pending, ~(1ull << (sig - 1)),
                            memory_order_relaxed);
  BLOCK_SIGNALS;
  _pthread_lock();
  for (e = dll_last(_pthread_list); e; e = dll_prev(_pthread_list, e)) {
    atomic_fetch_and_explicit(&POSIXTHREAD_CONTAINER(e)->tib->tib_sigpending,
                              ~(1ull << (sig - 1)), memory_order_relaxed);
  }
  _pthread_unlock();
  ALLOW_SIGNALS;
}

static textwindows int __sig_getter(atomic_ulong *sigs, sigset_t masked) {
  int sig;
  sigset_t bit, pending, deliverable;
  for (;;) {
    pending = atomic_load_explicit(sigs, memory_order_acquire);
    if ((deliverable = pending & ~masked)) {
      sig = _bsfl(deliverable) + 1;
      bit = 1ull << (sig - 1);
      if (atomic_fetch_and_explicit(sigs, ~bit, memory_order_acq_rel) & bit) {
        return sig;
      }
    } else {
      return 0;
    }
  }
}

textwindows int __sig_get(sigset_t masked) {
  int sig;
  if (!(sig = __sig_getter(&__get_tls()->tib_sigpending, masked))) {
    sig = __sig_getter(&__sig.pending, masked);
  }
  return sig;
}

static textwindows bool __sig_should_use_altstack(unsigned flags,
                                                  struct CosmoTib *tib) {
  if (!(flags & SA_ONSTACK)) {
    return false;  // signal handler didn't enable it
  }
  if (!tib->tib_sigstack_size) {
    return false;  // sigaltstack() wasn't installed on this thread
  }
  if (tib->tib_sigstack_flags & SS_DISABLE) {
    return false;  // sigaltstack() on this thread was disabled by user
  }
  char *bp = __builtin_frame_address(0);
  if (tib->tib_sigstack_addr <= bp &&
      bp <= tib->tib_sigstack_addr + tib->tib_sigstack_size) {
    return false;  // we're already on the alternate stack
  }
  return true;
}

static textwindows wontreturn void __sig_terminate(int sig) {
  TerminateThisProcess(sig);
}

static textwindows bool __sig_start(struct PosixThread *pt, int sig,
                                    unsigned *rva, unsigned *flags) {
  *rva = __sighandrvas[sig];
  *flags = __sighandflags[sig];
  if (*rva == (intptr_t)SIG_IGN ||
      (*rva == (intptr_t)SIG_DFL && __sig_ignored_by_default(sig))) {
    STRACE("ignoring %G", sig);
    return false;
  }
  if (atomic_load_explicit(&pt->tib->tib_sigmask, memory_order_acquire) &
      (1ull << (sig - 1))) {
    STRACE("enqueing %G on %d", sig, _pthread_tid(pt));
    atomic_fetch_or_explicit(&pt->tib->tib_sigpending, 1ull << (sig - 1),
                             memory_order_relaxed);
    return false;
  }
  if (*rva == (intptr_t)SIG_DFL) {
    STRACE("terminating on %G due to no handler", sig);
    __sig_terminate(sig);
  }
  return true;
}

static textwindows sigaction_f __sig_handler(unsigned rva) {
  atomic_fetch_add_explicit(&__sig.count, 1, memory_order_relaxed);
  return (sigaction_f)(__executable_start + rva);
}

textwindows int __sig_raise(volatile int sig, int sic) {

  // bitset of kinds of handlers called
  volatile int handler_was_called = 0;

  // loop over pending signals
  ucontext_t ctx;
  getcontext(&ctx);
  if (!sig) {
    if ((sig = __sig_get(ctx.uc_sigmask))) {
      sic = SI_KERNEL;
    } else {
      return handler_was_called;
    }
  }

  // process signal(s)
  unsigned rva, flags;
  struct PosixThread *pt = _pthread_self();
  if (__sig_start(pt, sig, &rva, &flags)) {
    if (flags & SA_RESETHAND) {
      STRACE("resetting %G handler", sig);
      __sighandrvas[sig] = (int32_t)(intptr_t)SIG_DFL;
    }

    // update the signal mask in preparation for signal handller
    sigset_t blocksigs = __sighandmask[sig];
    if (!(flags & SA_NODEFER)) blocksigs |= 1ull << (sig - 1);
    ctx.uc_sigmask = atomic_fetch_or_explicit(&pt->tib->tib_sigmask, blocksigs,
                                              memory_order_acquire);

    // call the user's signal handler
    char ssbuf[128];
    siginfo_t si = {.si_signo = sig, .si_code = sic};
    STRACE("__sig_raise(%G, %t) mask %s", sig, __sig_handler(rva),
           (DescribeSigset)(ssbuf, 0, (sigset_t *)&pt->tib->tib_sigmask));
    __sig_handler(rva)(sig, &si, &ctx);

    // record this handler
    if (flags & SA_RESTART) {
      handler_was_called |= SIG_HANDLED_SA_RESTART;
    } else {
      handler_was_called |= SIG_HANDLED_NO_RESTART;
    }
  }

  // restore sigmask
  // loop back to top
  // jump where handler says
  sig = 0;
  return setcontext(&ctx);
}

textwindows int __sig_relay(int sig, int sic, sigset_t waitmask) {
  sigset_t m;
  int handler_was_called;
  m = atomic_exchange_explicit(&__get_tls()->tib_sigmask, waitmask,
                               memory_order_acquire);
  handler_was_called = __sig_raise(sig, SI_KERNEL);
  atomic_store_explicit(&__get_tls()->tib_sigmask, m, memory_order_release);
  return handler_was_called;
}

// cancels blocking operations being performed by signaled thread
textwindows void __sig_cancel(struct PosixThread *pt, int sig, unsigned flags) {
  atomic_int *blocker;
  blocker = atomic_load_explicit(&pt->pt_blocker, memory_order_acquire);
  if (!blocker) {
    STRACE("%G sent to %d asynchronously", sig, _pthread_tid(pt));
    return;
  }
  // we can cancel another thread's overlapped i/o op after the freeze
  if (blocker == PT_BLOCKER_IO) {
    STRACE("%G canceling %d's i/o", sig, _pthread_tid(pt));
    CancelIoEx(pt->pt_iohandle, pt->pt_ioverlap);
    return;
  }
  // threads can create semaphores on an as-needed basis
  if (blocker == PT_BLOCKER_SEM) {
    STRACE("%G releasing %d's semaphore", sig, _pthread_tid(pt));
    ReleaseSemaphore(pt->pt_semaphore, 1, 0);
    return;
  }
  // all other blocking ops that aren't overlap should use futexes
  // we force restartable futexes to churn by waking w/o releasing
  STRACE("%G waking %d's futex", sig, _pthread_tid(pt));
  WakeByAddressSingle(blocker);
}

// the user's signal handler callback is wrapped with this trampoline
static textwindows wontreturn void __sig_tramp(struct SignalFrame *sf) {
  int sig = sf->si.si_signo;
  struct CosmoTib *tib = __get_tls();
  struct PosixThread *pt = (struct PosixThread *)tib->tib_pthread;
  for (;;) {

    // update the signal mask in preparation for signal handller
    sigset_t blocksigs = __sighandmask[sig];
    if (!(sf->flags & SA_NODEFER)) blocksigs |= 1ull << (sig - 1);
    sf->ctx.uc_sigmask = atomic_fetch_or_explicit(&tib->tib_sigmask, blocksigs,
                                                  memory_order_acquire);

    // call the user's signal handler
    char ssbuf[2][128];
    STRACE("__sig_tramp(%G, %t) mask %s → %s", sig, __sig_handler(sf->rva),
           (DescribeSigset)(ssbuf[0], 0, &sf->ctx.uc_sigmask),
           (DescribeSigset)(ssbuf[1], 0, (sigset_t *)&tib->tib_sigmask));
    __sig_handler(sf->rva)(sig, &sf->si, &sf->ctx);

    // restore the signal mask that was used by the interrupted code
    // this may have been modified by the signal handler in the callback
    atomic_store_explicit(&tib->tib_sigmask, sf->ctx.uc_sigmask,
                          memory_order_release);

    // jump back into original code if there aren't any pending signals
    do {
      if (!(sig = __sig_get(sf->ctx.uc_sigmask))) {
        __sig_restore(&sf->ctx);
      }
    } while (!__sig_start(pt, sig, &sf->rva, &sf->flags));

    // tail recurse into another signal handler
    sf->si.si_signo = sig;
    sf->si.si_code = SI_KERNEL;
    if (sf->flags & SA_RESETHAND) {
      STRACE("resetting %G handler", sig);
      __sighandrvas[sig] = (int32_t)(intptr_t)SIG_DFL;
    }
  }
}

// sends signal to another specific thread which is ref'd
static int __sig_killer(struct PosixThread *pt, int sig, int sic) {
  unsigned rva = __sighandrvas[sig];
  unsigned flags = __sighandflags[sig];

  // do nothing if signal is ignored
  if (rva == (intptr_t)SIG_IGN ||
      (rva == (intptr_t)SIG_DFL && __sig_ignored_by_default(sig))) {
    STRACE("ignoring %G", sig);
    return 0;
  }

  // if there's no handler then killing a thread kills the process
  if (rva == (intptr_t)SIG_DFL) {
    STRACE("terminating on %G due to no handler", sig);
    __sig_terminate(sig);
  }

  // ignore signals already pending
  uintptr_t th = _pthread_syshand(pt);
  if (atomic_load_explicit(&pt->tib->tib_sigpending, memory_order_acquire) &
      (1ull << (sig - 1))) {
    return 0;
  }

  // take control of thread
  // suspending the thread happens asynchronously
  // however getting the context blocks until it's frozen
  static pthread_spinlock_t killer_lock;
  pthread_spin_lock(&killer_lock);
  if (SuspendThread(th) == -1u) {
    STRACE("SuspendThread failed w/ %d", GetLastError());
    pthread_spin_unlock(&killer_lock);
    return ESRCH;
  }
  struct NtContext nc;
  nc.ContextFlags = kNtContextFull;
  if (!GetThreadContext(th, &nc)) {
    STRACE("GetThreadContext failed w/ %d", GetLastError());
    ResumeThread(th);
    pthread_spin_unlock(&killer_lock);
    return ESRCH;
  }
  pthread_spin_unlock(&killer_lock);

  // we can't preempt threads that masked sig or are blocked
  // we can't preempt threads that are running in win32 code
  // so we shall unblock the thread and let it signal itself
  if ((atomic_load_explicit(&pt->tib->tib_sigmask, memory_order_acquire) &
       (1ull << (sig - 1))) ||
      !((uintptr_t)__executable_start <= nc.Rip &&
        nc.Rip < (uintptr_t)__privileged_start)) {
    atomic_fetch_or_explicit(&pt->tib->tib_sigpending, 1ull << (sig - 1),
                             memory_order_relaxed);
    ResumeThread(th);
    __sig_cancel(pt, sig, flags);
    return 0;
  }

  // preferring to live dangerously
  // the thread will be signaled asynchronously
  if (flags & SA_RESETHAND) {
    STRACE("resetting %G handler", sig);
    __sighandrvas[sig] = (int32_t)(intptr_t)SIG_DFL;
  }

  // inject call to trampoline function into thread
  uintptr_t sp;
  if (__sig_should_use_altstack(flags, pt->tib)) {
    sp = (uintptr_t)pt->tib->tib_sigstack_addr + pt->tib->tib_sigstack_size;
  } else {
    sp = nc.Rsp;
  }
  sp -= sizeof(struct SignalFrame);
  sp &= -16;
  struct SignalFrame *sf = (struct SignalFrame *)sp;
  _ntcontext2linux(&sf->ctx, &nc);
  bzero(&sf->si, sizeof(sf->si));
  sf->rva = rva;
  sf->flags = flags;
  sf->si.si_code = sic;
  sf->si.si_signo = sig;
  *(uintptr_t *)(sp -= sizeof(uintptr_t)) = nc.Rip;
  nc.Rip = (intptr_t)__sig_tramp;
  nc.Rdi = (intptr_t)sf;
  nc.Rsp = sp;
  if (!SetThreadContext(th, &nc)) {
    STRACE("SetThreadContext failed w/ %d", GetLastError());
    return ESRCH;
  }
  ResumeThread(th);
  __sig_cancel(pt, sig, flags);
  return 0;
}

// sends signal to another specific thread
textwindows int __sig_kill(struct PosixThread *pt, int sig, int sic) {
  int rc;
  BLOCK_SIGNALS;
  _pthread_ref(pt);
  rc = __sig_killer(pt, sig, sic);
  _pthread_unref(pt);
  ALLOW_SIGNALS;
  return rc;
}

// sends signal to any other thread
textwindows void __sig_generate(int sig, int sic) {
  struct Dll *e;
  struct PosixThread *pt, *mark = 0;
  if (__sig_ignored(sig)) {
    STRACE("ignoring %G", sig);
    return;
  }
  if (__sighandrvas[sig] == (intptr_t)SIG_DFL) {
    STRACE("terminating on %G due to no handler", sig);
    __sig_terminate(sig);
  }
  if (atomic_load_explicit(&__sig.pending, memory_order_acquire) &
      (1ull << (sig - 1))) {
    return;
  }
  BLOCK_SIGNALS;
  _pthread_lock();
  for (e = dll_first(_pthread_list); e; e = dll_next(_pthread_list, e)) {
    pt = POSIXTHREAD_CONTAINER(e);
    // we don't want to signal ourself
    if (pt == _pthread_self()) continue;
    // we don't want to signal a thread that isn't running
    if (atomic_load_explicit(&pt->pt_status, memory_order_acquire) >=
        kPosixThreadTerminated) {
      continue;
    }
    // choose this thread if it isn't masking sig
    if (!(atomic_load_explicit(&pt->tib->tib_sigmask, memory_order_acquire) &
          (1ull << (sig - 1)))) {
      _pthread_ref(pt);
      mark = pt;
      break;
    }
    // if a thread is blocking then we check to see if it's planning
    // to unblock our sig once the wait operation is completed; when
    // that's the case we can cancel the thread's i/o to deliver sig
    if (atomic_load_explicit(&pt->pt_blocker, memory_order_acquire) &&
        !(atomic_load_explicit(&pt->pt_blkmask, memory_order_relaxed) &
          (1ull << (sig - 1)))) {
      _pthread_ref(pt);
      mark = pt;
      break;
    }
  }
  _pthread_unlock();
  if (mark) {
    __sig_killer(mark, sig, sic);
    _pthread_unref(mark);
  } else {
    atomic_fetch_or_explicit(&__sig.pending, 1ull << (sig - 1),
                             memory_order_relaxed);
  }
  ALLOW_SIGNALS;
}

static int __sig_crash_sig(struct NtExceptionPointers *ep, int *code) {
  switch (ep->ExceptionRecord->ExceptionCode) {
    case kNtSignalBreakpoint:
      *code = TRAP_BRKPT;
      return SIGTRAP;
    case kNtSignalIllegalInstruction:
      *code = ILL_ILLOPC;
      return SIGILL;
    case kNtSignalPrivInstruction:
      *code = ILL_PRVOPC;
      return SIGILL;
    case kNtSignalInPageError:
    case kNtStatusStackOverflow:
      *code = SEGV_MAPERR;
      return SIGSEGV;
    case kNtSignalGuardPage:
    case kNtSignalAccessViolation:
      *code = SEGV_ACCERR;
      return SIGSEGV;
    case kNtSignalInvalidHandle:
    case kNtSignalInvalidParameter:
    case kNtSignalAssertionFailure:
      *code = SI_USER;
      return SIGABRT;
    case kNtStatusIntegerOverflow:
      *code = FPE_INTOVF;
      return SIGFPE;
    case kNtSignalFltDivideByZero:
      *code = FPE_FLTDIV;
      return SIGFPE;
    case kNtSignalFltOverflow:
      *code = FPE_FLTOVF;
      return SIGFPE;
    case kNtSignalFltUnderflow:
      *code = FPE_FLTUND;
      return SIGFPE;
    case kNtSignalFltInexactResult:
      *code = FPE_FLTRES;
      return SIGFPE;
    case kNtSignalFltDenormalOperand:
    case kNtSignalFltInvalidOperation:
    case kNtSignalFltStackCheck:
    case kNtSignalIntegerDivideByZero:
    case kNtSignalFloatMultipleFaults:
    case kNtSignalFloatMultipleTraps:
      *code = FPE_FLTINV;
      return SIGFPE;
    case kNtSignalDllNotFound:
    case kNtSignalOrdinalNotFound:
    case kNtSignalEntrypointNotFound:
    case kNtSignalDllInitFailed:
      *code = SI_KERNEL;
      return SIGSYS;
    default:
      *code = ep->ExceptionRecord->ExceptionCode;
      return SIGSEGV;
  }
}

static void __sig_unmaskable(struct NtExceptionPointers *ep, int code, int sig,
                             struct CosmoTib *tib) {

  // log vital crash information reliably for --strace before doing much
  // we don't print this without the flag since raw numbers scare people
  // this needs at least one page of stack memory in order to get logged
  // otherwise it'll print a warning message about the lack of stack mem
  STRACE("win32 vectored exception 0x%08Xu raising %G "
         "cosmoaddr2line %s %lx %s",
         ep->ExceptionRecord->ExceptionCode, sig, program_invocation_name,
         ep->ContextRecord->Rip,
         DescribeBacktrace((struct StackFrame *)ep->ContextRecord->Rbp));

  // if the user didn't install a signal handler for this unmaskable
  // exception, then print a friendly helpful hint message to stderr
  unsigned rva = __sighandrvas[sig];
  if (rva == (intptr_t)SIG_DFL || rva == (intptr_t)SIG_IGN) {
#ifndef TINY
    intptr_t hStderr;
    char sigbuf[21], s[128], *p;
    hStderr = GetStdHandle(kNtStdErrorHandle);
    p = stpcpy(s, "Terminating on uncaught ");
    p = stpcpy(p, strsignal_r(sig, sigbuf));
    p = stpcpy(p, ". Pass --strace and/or ShowCrashReports() for details.\n");
    WriteFile(hStderr, s, p - s, 0, 0);
#endif
    __sig_terminate(sig);
  }

  // if this signal handler is configured to auto-reset to the default
  // then that reset needs to happen before the user handler is called
  unsigned flags = __sighandflags[sig];
  if (flags & SA_RESETHAND) {
    STRACE("resetting %G handler", sig);
    __sighandrvas[sig] = (int32_t)(intptr_t)SIG_DFL;
  }

  // determine the true memory address at which fault occurred
  // if this is a stack overflow then reapply guard protection
  void *si_addr;
  if (ep->ExceptionRecord->ExceptionCode == kNtSignalGuardPage) {
    si_addr = (void *)ep->ExceptionRecord->ExceptionInformation[1];
  } else {
    si_addr = ep->ExceptionRecord->ExceptionAddress;
  }

  // call the user signal handler
  // with a temporarily replaced signal mask
  // and a modifiable view of the faulting code's cpu state
  // note ucontext_t is a hefty data structures on top of NtContext
  ucontext_t ctx = {0};
  siginfo_t si = {.si_signo = sig, .si_code = code, .si_addr = si_addr};
  _ntcontext2linux(&ctx, ep->ContextRecord);
  sigset_t blocksigs = __sighandmask[sig];
  if (!(flags & SA_NODEFER)) blocksigs |= 1ull << (sig - 1);
  ctx.uc_sigmask = atomic_fetch_or_explicit(&tib->tib_sigmask, blocksigs,
                                            memory_order_acquire);
  __sig_handler(rva)(sig, &si, &ctx);
  atomic_store_explicit(&tib->tib_sigmask, ctx.uc_sigmask,
                        memory_order_release);
  _ntlinux2context(ep->ContextRecord, &ctx);
}

void __stack_call(struct NtExceptionPointers *, int, int, struct CosmoTib *,
                  void (*)(struct NtExceptionPointers *, int, int,
                           struct CosmoTib *),
                  void *);

//                         abashed the devil stood
//                      and felt how awful goodness is
__msabi dontinstrument unsigned __sig_crash(struct NtExceptionPointers *ep) {

  // translate win32 to unix si_signo and si_code
  int code, sig = __sig_crash_sig(ep, &code);

  // advance the instruction pointer to skip over debugger breakpoints
  // this behavior is consistent with how unix kernels are implemented
  if (sig == SIGTRAP) {
    ep->ContextRecord->Rip++;
    if (__sig_ignored(sig)) {
      return kNtExceptionContinueExecution;
    }
  }

  // win32 stack overflow detection executes INSIDE the guard page
  // thus switch to the alternate signal stack as soon as possible
  struct CosmoTib *tib = __get_tls();
  unsigned flags = __sighandflags[sig];
  if (__sig_should_use_altstack(flags, tib)) {
    __stack_call(ep, code, sig, tib, __sig_unmaskable,
                 tib->tib_sigstack_addr + tib->tib_sigstack_size);
  } else {
    __sig_unmaskable(ep, code, sig, tib);
  }

  // resume running user program
  // hopefully the user fixed the cpu state
  // otherwise the crash will keep happening
  return kNtExceptionContinueExecution;
}

static textwindows int __sig_console_sig(uint32_t dwCtrlType) {
  switch (dwCtrlType) {
    case kNtCtrlCEvent:
      return SIGINT;
    case kNtCtrlBreakEvent:
      return SIGQUIT;
    case kNtCtrlCloseEvent:
    case kNtCtrlLogoffEvent:    // only received by services
    case kNtCtrlShutdownEvent:  // only received by services
      return SIGHUP;
    default:
      return SIGSTKFLT;
  }
}

__msabi textwindows dontinstrument bool32 __sig_console(uint32_t dwCtrlType) {
  struct CosmoTib tls;
  __bootstrap_tls(&tls, __builtin_frame_address(0));
  __sig_generate(__sig_console_sig(dwCtrlType), SI_KERNEL);
  return true;
}

// returns 0 if no signal handlers were called, otherwise a bitmask
// consisting of `1` which means a signal handler was invoked which
// didn't have the SA_RESTART flag, and `2`, which means SA_RESTART
// handlers were called (or `3` if both were the case).
textwindows int __sig_check(void) {
  int sig;
  if ((sig = __sig_get(atomic_load_explicit(&__get_tls()->tib_sigmask,
                                            memory_order_acquire)))) {
    return __sig_raise(sig, SI_KERNEL);
  } else {
    return 0;
  }
}

textstartup void __sig_init(void) {
  if (!IsWindows()) return;
  AddVectoredExceptionHandler(true, (void *)__sig_crash);
  SetConsoleCtrlHandler((void *)__sig_console, true);
}

const void *const __sig_ctor[] initarray = {__sig_init};

#endif /* __x86_64__ */