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path: root/tools/profiler/core/platform-linux-android.cpp
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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
// Copyright (c) 2006-2011 The Chromium Authors. All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//  * Redistributions of source code must retain the above copyright
//    notice, this list of conditions and the following disclaimer.
//  * Redistributions in binary form must reproduce the above copyright
//    notice, this list of conditions and the following disclaimer in
//    the documentation and/or other materials provided with the
//    distribution.
//  * Neither the name of Google, Inc. nor the names of its contributors
//    may be used to endorse or promote products derived from this
//    software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
// FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
// COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
// BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
// OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
// AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
// OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
// SUCH DAMAGE.

// This file is used for both Linux and Android as well as FreeBSD.

#include <stdio.h>
#include <math.h>

#include <pthread.h>
#if defined(GP_OS_freebsd)
#  include <sys/thr.h>
#endif
#include <semaphore.h>
#include <signal.h>
#include <sys/time.h>
#include <sys/resource.h>
#include <sys/syscall.h>
#include <sys/types.h>
#include <stdlib.h>
#include <sched.h>
#include <ucontext.h>
// Ubuntu Dapper requires memory pages to be marked as
// executable. Otherwise, OS raises an exception when executing code
// in that page.
#include <sys/types.h>  // mmap & munmap
#include <sys/mman.h>   // mmap & munmap
#include <sys/stat.h>   // open
#include <fcntl.h>      // open
#include <unistd.h>     // sysconf
#include <semaphore.h>
#ifdef __GLIBC__
#  include <execinfo.h>  // backtrace, backtrace_symbols
#endif                   // def __GLIBC__
#include <strings.h>     // index
#include <errno.h>
#include <stdarg.h>

#include "prenv.h"
#include "mozilla/PodOperations.h"
#include "mozilla/DebugOnly.h"
#if defined(GP_OS_linux) || defined(GP_OS_android)
#  include "common/linux/breakpad_getcontext.h"
#endif

#include <string.h>
#include <list>

using namespace mozilla;

static void PopulateRegsFromContext(Registers& aRegs, ucontext_t* aContext) {
  aRegs.mContext = aContext;
  mcontext_t& mcontext = aContext->uc_mcontext;

  // Extracting the sample from the context is extremely machine dependent.
#if defined(GP_PLAT_x86_linux) || defined(GP_PLAT_x86_android)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.gregs[REG_EIP]);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.gregs[REG_ESP]);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.gregs[REG_EBP]);
  aRegs.mLR = 0;
#elif defined(GP_PLAT_amd64_linux) || defined(GP_PLAT_amd64_android)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.gregs[REG_RIP]);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.gregs[REG_RSP]);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.gregs[REG_RBP]);
  aRegs.mLR = 0;
#elif defined(GP_PLAT_amd64_freebsd)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.mc_rip);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.mc_rsp);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.mc_rbp);
  aRegs.mLR = 0;
#elif defined(GP_PLAT_arm_linux) || defined(GP_PLAT_arm_android)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.arm_pc);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.arm_sp);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.arm_fp);
  aRegs.mLR = reinterpret_cast<Address>(mcontext.arm_lr);
#elif defined(GP_PLAT_arm64_linux) || defined(GP_PLAT_arm64_android)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.pc);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.sp);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.regs[29]);
  aRegs.mLR = reinterpret_cast<Address>(mcontext.regs[30]);
#elif defined(GP_PLAT_arm64_freebsd)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.mc_gpregs.gp_elr);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.mc_gpregs.gp_sp);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.mc_gpregs.gp_x[29]);
  aRegs.mLR = reinterpret_cast<Address>(mcontext.mc_gpregs.gp_lr);
#elif defined(GP_PLAT_mips64_linux) || defined(GP_PLAT_mips64_android)
  aRegs.mPC = reinterpret_cast<Address>(mcontext.pc);
  aRegs.mSP = reinterpret_cast<Address>(mcontext.gregs[29]);
  aRegs.mFP = reinterpret_cast<Address>(mcontext.gregs[30]);

#else
#  error "bad platform"
#endif
}

#if defined(GP_OS_android)
#  define SYS_tgkill __NR_tgkill
#endif

#if defined(GP_OS_linux) || defined(GP_OS_android)
int tgkill(pid_t tgid, pid_t tid, int signalno) {
  return syscall(SYS_tgkill, tgid, tid, signalno);
}
#endif

#if defined(GP_OS_freebsd)
#  define tgkill thr_kill2
#endif

mozilla::profiler::PlatformData::PlatformData(ProfilerThreadId aThreadId) {
  MOZ_ASSERT(aThreadId == profiler_current_thread_id());
  if (clockid_t clockid; pthread_getcpuclockid(pthread_self(), &clockid) == 0) {
    mClockId = Some(clockid);
  }
}

mozilla::profiler::PlatformData::~PlatformData() = default;

////////////////////////////////////////////////////////////////////////
// BEGIN Sampler target specifics

// The only way to reliably interrupt a Linux thread and inspect its register
// and stack state is by sending a signal to it, and doing the work inside the
// signal handler.  But we don't want to run much code inside the signal
// handler, since POSIX severely restricts what we can do in signal handlers.
// So we use a system of semaphores to suspend the thread and allow the
// sampler thread to do all the work of unwinding and copying out whatever
// data it wants.
//
// A four-message protocol is used to reliably suspend and later resume the
// thread to be sampled (the samplee):
//
// Sampler (signal sender) thread              Samplee (thread to be sampled)
//
// Prepare the SigHandlerCoordinator
// and point sSigHandlerCoordinator at it
//
// send SIGPROF to samplee ------- MSG 1 ----> (enter signal handler)
// wait(mMessage2)                             Copy register state
//                                               into sSigHandlerCoordinator
//                         <------ MSG 2 ----- post(mMessage2)
// Samplee is now suspended.                   wait(mMessage3)
//   Examine its stack/register
//   state at leisure
//
// Release samplee:
//   post(mMessage3)       ------- MSG 3 ----->
// wait(mMessage4)                              Samplee now resumes.  Tell
//                                                the sampler that we are done.
//                         <------ MSG 4 ------ post(mMessage4)
// Now we know the samplee's signal             (leave signal handler)
//   handler has finished using
//   sSigHandlerCoordinator.  We can
//   safely reuse it for some other thread.
//

// A type used to coordinate between the sampler (signal sending) thread and
// the thread currently being sampled (the samplee, which receives the
// signals).
//
// The first message is sent using a SIGPROF signal delivery.  The subsequent
// three are sent using sem_wait/sem_post pairs.  They are named accordingly
// in the following struct.
struct SigHandlerCoordinator {
  SigHandlerCoordinator() {
    PodZero(&mUContext);
    int r = sem_init(&mMessage2, /* pshared */ 0, 0);
    r |= sem_init(&mMessage3, /* pshared */ 0, 0);
    r |= sem_init(&mMessage4, /* pshared */ 0, 0);
    MOZ_ASSERT(r == 0);
    (void)r;
  }

  ~SigHandlerCoordinator() {
    int r = sem_destroy(&mMessage2);
    r |= sem_destroy(&mMessage3);
    r |= sem_destroy(&mMessage4);
    MOZ_ASSERT(r == 0);
    (void)r;
  }

  sem_t mMessage2;       // To sampler: "context is in sSigHandlerCoordinator"
  sem_t mMessage3;       // To samplee: "resume"
  sem_t mMessage4;       // To sampler: "finished with sSigHandlerCoordinator"
  ucontext_t mUContext;  // Context at signal
};

struct SigHandlerCoordinator* Sampler::sSigHandlerCoordinator = nullptr;

static void SigprofHandler(int aSignal, siginfo_t* aInfo, void* aContext) {
  // Avoid TSan warning about clobbering errno.
  int savedErrno = errno;

  MOZ_ASSERT(aSignal == SIGPROF);
  MOZ_ASSERT(Sampler::sSigHandlerCoordinator);

  // By sending us this signal, the sampler thread has sent us message 1 in
  // the comment above, with the meaning "|sSigHandlerCoordinator| is ready
  // for use, please copy your register context into it."
  Sampler::sSigHandlerCoordinator->mUContext =
      *static_cast<ucontext_t*>(aContext);

  // Send message 2: tell the sampler thread that the context has been copied
  // into |sSigHandlerCoordinator->mUContext|.  sem_post can never fail by
  // being interrupted by a signal, so there's no loop around this call.
  int r = sem_post(&Sampler::sSigHandlerCoordinator->mMessage2);
  MOZ_ASSERT(r == 0);

  // At this point, the sampler thread assumes we are suspended, so we must
  // not touch any global state here.

  // Wait for message 3: the sampler thread tells us to resume.
  while (true) {
    r = sem_wait(&Sampler::sSigHandlerCoordinator->mMessage3);
    if (r == -1 && errno == EINTR) {
      // Interrupted by a signal.  Try again.
      continue;
    }
    // We don't expect any other kind of failure
    MOZ_ASSERT(r == 0);
    break;
  }

  // Send message 4: tell the sampler thread that we are finished accessing
  // |sSigHandlerCoordinator|.  After this point it is not safe to touch
  // |sSigHandlerCoordinator|.
  r = sem_post(&Sampler::sSigHandlerCoordinator->mMessage4);
  MOZ_ASSERT(r == 0);

  errno = savedErrno;
}

Sampler::Sampler(PSLockRef aLock)
    : mMyPid(profiler_current_process_id()),
      // We don't know what the sampler thread's ID will be until it runs, so
      // set mSamplerTid to a dummy value and fill it in for real in
      // SuspendAndSampleAndResumeThread().
      mSamplerTid{} {
#if defined(USE_EHABI_STACKWALK)
  mozilla::EHABIStackWalkInit();
#endif

  // NOTE: We don't initialize LUL here, instead initializing it in
  // SamplerThread's constructor. This is because with the
  // profiler_suspend_and_sample_thread entry point, we want to be able to
  // sample without waiting for LUL to be initialized.

  // Request profiling signals.
  struct sigaction sa;
  sa.sa_sigaction = SigprofHandler;
  sigemptyset(&sa.sa_mask);
  sa.sa_flags = SA_RESTART | SA_SIGINFO;
  if (sigaction(SIGPROF, &sa, &mOldSigprofHandler) != 0) {
    MOZ_CRASH("Error installing SIGPROF handler in the profiler");
  }
}

void Sampler::Disable(PSLockRef aLock) {
  // Restore old signal handler. This is global state so it's important that
  // we do it now, while gPSMutex is locked.
  sigaction(SIGPROF, &mOldSigprofHandler, 0);
}

static void StreamMetaPlatformSampleUnits(PSLockRef aLock,
                                          SpliceableJSONWriter& aWriter) {
  aWriter.StringProperty("threadCPUDelta", "ns");
}

/* static */
uint64_t RunningTimes::ConvertRawToJson(uint64_t aRawValue) {
  return aRawValue;
}

namespace mozilla::profiler {
bool GetCpuTimeSinceThreadStartInNs(
    uint64_t* aResult, const mozilla::profiler::PlatformData& aPlatformData) {
  Maybe<clockid_t> maybeCid = aPlatformData.GetClockId();
  if (MOZ_UNLIKELY(!maybeCid)) {
    return false;
  }

  timespec t;
  if (clock_gettime(*maybeCid, &t) != 0) {
    return false;
  }

  *aResult = uint64_t(t.tv_sec) * 1'000'000'000u + uint64_t(t.tv_nsec);
  return true;
}
}  // namespace mozilla::profiler

static RunningTimes GetProcessRunningTimesDiff(
    PSLockRef aLock, RunningTimes& aPreviousRunningTimesToBeUpdated) {
  AUTO_PROFILER_STATS(GetProcessRunningTimes);

  RunningTimes newRunningTimes;
  {
    AUTO_PROFILER_STATS(GetProcessRunningTimes_clock_gettime);
    if (timespec ts; clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &ts) == 0) {
      newRunningTimes.SetThreadCPUDelta(uint64_t(ts.tv_sec) * 1'000'000'000u +
                                        uint64_t(ts.tv_nsec));
    }
    newRunningTimes.SetPostMeasurementTimeStamp(TimeStamp::Now());
  };

  const RunningTimes diff = newRunningTimes - aPreviousRunningTimesToBeUpdated;
  aPreviousRunningTimesToBeUpdated = newRunningTimes;
  return diff;
}

static RunningTimes GetThreadRunningTimesDiff(
    PSLockRef aLock,
    ThreadRegistration::UnlockedRWForLockedProfiler& aThreadData) {
  AUTO_PROFILER_STATS(GetRunningTimes_clock_gettime_thread);

  const mozilla::profiler::PlatformData& platformData =
      aThreadData.PlatformDataCRef();
  Maybe<clockid_t> maybeCid = platformData.GetClockId();

  if (MOZ_UNLIKELY(!maybeCid)) {
    // No clock id -> Nothing to measure apart from the timestamp.
    RunningTimes emptyRunningTimes;
    emptyRunningTimes.SetPostMeasurementTimeStamp(TimeStamp::Now());
    return emptyRunningTimes;
  }

  const RunningTimes newRunningTimes = GetRunningTimesWithTightTimestamp(
      [cid = *maybeCid](RunningTimes& aRunningTimes) {
        AUTO_PROFILER_STATS(GetRunningTimes_clock_gettime);
        if (timespec ts; clock_gettime(cid, &ts) == 0) {
          aRunningTimes.ResetThreadCPUDelta(
              uint64_t(ts.tv_sec) * 1'000'000'000u + uint64_t(ts.tv_nsec));
        } else {
          aRunningTimes.ClearThreadCPUDelta();
        }
      });

  ProfiledThreadData* profiledThreadData =
      aThreadData.GetProfiledThreadData(aLock);
  MOZ_ASSERT(profiledThreadData);
  RunningTimes& previousRunningTimes =
      profiledThreadData->PreviousThreadRunningTimesRef();
  const RunningTimes diff = newRunningTimes - previousRunningTimes;
  previousRunningTimes = newRunningTimes;
  return diff;
}

static void DiscardSuspendedThreadRunningTimes(
    PSLockRef aLock,
    ThreadRegistration::UnlockedRWForLockedProfiler& aThreadData) {
  AUTO_PROFILER_STATS(DiscardSuspendedThreadRunningTimes);

  // On Linux, suspending a thread uses a signal that makes that thread work
  // to handle it. So we want to discard any added running time since the call
  // to GetThreadRunningTimesDiff, which is done by overwriting the thread's
  // PreviousThreadRunningTimesRef() with the current running time now.

  const mozilla::profiler::PlatformData& platformData =
      aThreadData.PlatformDataCRef();
  Maybe<clockid_t> maybeCid = platformData.GetClockId();

  if (MOZ_UNLIKELY(!maybeCid)) {
    // No clock id -> Nothing to measure.
    return;
  }

  ProfiledThreadData* profiledThreadData =
      aThreadData.GetProfiledThreadData(aLock);
  MOZ_ASSERT(profiledThreadData);
  RunningTimes& previousRunningTimes =
      profiledThreadData->PreviousThreadRunningTimesRef();

  if (timespec ts; clock_gettime(*maybeCid, &ts) == 0) {
    previousRunningTimes.ResetThreadCPUDelta(
        uint64_t(ts.tv_sec) * 1'000'000'000u + uint64_t(ts.tv_nsec));
  } else {
    previousRunningTimes.ClearThreadCPUDelta();
  }
}

template <typename Func>
void Sampler::SuspendAndSampleAndResumeThread(
    PSLockRef aLock,
    const ThreadRegistration::UnlockedReaderAndAtomicRWOnThread& aThreadData,
    const TimeStamp& aNow, const Func& aProcessRegs) {
  // Only one sampler thread can be sampling at once.  So we expect to have
  // complete control over |sSigHandlerCoordinator|.
  MOZ_ASSERT(!sSigHandlerCoordinator);

  if (!mSamplerTid.IsSpecified()) {
    mSamplerTid = profiler_current_thread_id();
  }
  ProfilerThreadId sampleeTid = aThreadData.Info().ThreadId();
  MOZ_RELEASE_ASSERT(sampleeTid != mSamplerTid);

  //----------------------------------------------------------------//
  // Suspend the samplee thread and get its context.

  SigHandlerCoordinator coord;  // on sampler thread's stack
  sSigHandlerCoordinator = &coord;

  // Send message 1 to the samplee (the thread to be sampled), by
  // signalling at it.
  // This could fail if the thread doesn't exist anymore.
  int r = tgkill(mMyPid.ToNumber(), sampleeTid.ToNumber(), SIGPROF);
  if (r == 0) {
    // Wait for message 2 from the samplee, indicating that the context
    // is available and that the thread is suspended.
    while (true) {
      r = sem_wait(&sSigHandlerCoordinator->mMessage2);
      if (r == -1 && errno == EINTR) {
        // Interrupted by a signal.  Try again.
        continue;
      }
      // We don't expect any other kind of failure.
      MOZ_ASSERT(r == 0);
      break;
    }

    //----------------------------------------------------------------//
    // Sample the target thread.

    // WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING
    //
    // The profiler's "critical section" begins here.  In the critical section,
    // we must not do any dynamic memory allocation, nor try to acquire any lock
    // or any other unshareable resource.  This is because the thread to be
    // sampled has been suspended at some entirely arbitrary point, and we have
    // no idea which unsharable resources (locks, essentially) it holds.  So any
    // attempt to acquire any lock, including the implied locks used by the
    // malloc implementation, risks deadlock.  This includes TimeStamp::Now(),
    // which gets a lock on Windows.

    // The samplee thread is now frozen and sSigHandlerCoordinator->mUContext is
    // valid.  We can poke around in it and unwind its stack as we like.

    // Extract the current register values.
    Registers regs;
    PopulateRegsFromContext(regs, &sSigHandlerCoordinator->mUContext);
    aProcessRegs(regs, aNow);

    //----------------------------------------------------------------//
    // Resume the target thread.

    // Send message 3 to the samplee, which tells it to resume.
    r = sem_post(&sSigHandlerCoordinator->mMessage3);
    MOZ_ASSERT(r == 0);

    // Wait for message 4 from the samplee, which tells us that it has
    // finished with |sSigHandlerCoordinator|.
    while (true) {
      r = sem_wait(&sSigHandlerCoordinator->mMessage4);
      if (r == -1 && errno == EINTR) {
        continue;
      }
      MOZ_ASSERT(r == 0);
      break;
    }

    // The profiler's critical section ends here.  After this point, none of the
    // critical section limitations documented above apply.
    //
    // WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING
  }

  // This isn't strictly necessary, but doing so does help pick up anomalies
  // in which the signal handler is running when it shouldn't be.
  sSigHandlerCoordinator = nullptr;
}

// END Sampler target specifics
////////////////////////////////////////////////////////////////////////

////////////////////////////////////////////////////////////////////////
// BEGIN SamplerThread target specifics

static void* ThreadEntry(void* aArg) {
  auto thread = static_cast<SamplerThread*>(aArg);
  thread->Run();
  return nullptr;
}

SamplerThread::SamplerThread(PSLockRef aLock, uint32_t aActivityGeneration,
                             double aIntervalMilliseconds, uint32_t aFeatures)
    : mSampler(aLock),
      mActivityGeneration(aActivityGeneration),
      mIntervalMicroseconds(
          std::max(1, int(floor(aIntervalMilliseconds * 1000 + 0.5)))) {
#if defined(USE_LUL_STACKWALK)
  lul::LUL* lul = CorePS::Lul();
  if (!lul && ProfilerFeature::HasStackWalk(aFeatures)) {
    CorePS::SetLul(MakeUnique<lul::LUL>(logging_sink_for_LUL));
    // Read all the unwind info currently available.
    lul = CorePS::Lul();
    read_procmaps(lul);

    // Switch into unwind mode. After this point, we can't add or remove any
    // unwind info to/from this LUL instance. The only thing we can do with
    // it is Unwind() calls.
    lul->EnableUnwinding();

    // Has a test been requested?
    if (PR_GetEnv("MOZ_PROFILER_LUL_TEST")) {
      int nTests = 0, nTestsPassed = 0;
      RunLulUnitTests(&nTests, &nTestsPassed, lul);
    }
  }
#endif

  // Start the sampling thread. It repeatedly sends a SIGPROF signal. Sending
  // the signal ourselves instead of relying on itimer provides much better
  // accuracy.
  //
  // At least 350 KiB of stack space are needed when built with TSAN. This
  // includes lul::N_STACK_BYTES plus whatever else is needed for the sampler
  // thread. Set the stack size to 800 KiB to keep a safe margin above that.
  pthread_attr_t attr;
  if (pthread_attr_init(&attr) != 0 ||
      pthread_attr_setstacksize(&attr, 800 * 1024) != 0 ||
      pthread_create(&mThread, &attr, ThreadEntry, this) != 0) {
    MOZ_CRASH("pthread_create failed");
  }
  pthread_attr_destroy(&attr);
}

SamplerThread::~SamplerThread() {
  pthread_join(mThread, nullptr);
  // Just in the unlikely case some callbacks were added between the end of the
  // thread and now.
  InvokePostSamplingCallbacks(std::move(mPostSamplingCallbackList),
                              SamplingState::JustStopped);
}

void SamplerThread::SleepMicro(uint32_t aMicroseconds) {
  if (aMicroseconds >= 1000000) {
    // Use usleep for larger intervals, because the nanosleep
    // code below only supports intervals < 1 second.
    MOZ_ALWAYS_TRUE(!::usleep(aMicroseconds));
    return;
  }

  struct timespec ts;
  ts.tv_sec = 0;
  ts.tv_nsec = aMicroseconds * 1000UL;

  int rv = ::nanosleep(&ts, &ts);

  while (rv != 0 && errno == EINTR) {
    // Keep waiting in case of interrupt.
    // nanosleep puts the remaining time back into ts.
    rv = ::nanosleep(&ts, &ts);
  }

  MOZ_ASSERT(!rv, "nanosleep call failed");
}

void SamplerThread::Stop(PSLockRef aLock) {
  // Restore old signal handler. This is global state so it's important that
  // we do it now, while gPSMutex is locked. It's safe to do this now even
  // though this SamplerThread is still alive, because the next time the main
  // loop of Run() iterates it won't get past the mActivityGeneration check,
  // and so won't send any signals.
  mSampler.Disable(aLock);
}

// END SamplerThread target specifics
////////////////////////////////////////////////////////////////////////

#if defined(GP_OS_linux) || defined(GP_OS_freebsd)

// We use pthread_atfork() to temporarily disable signal delivery during any
// fork() call. Without that, fork() can be repeatedly interrupted by signal
// delivery, requiring it to be repeatedly restarted, which can lead to *long*
// delays. See bug 837390.
//
// We provide no paf_child() function to run in the child after forking. This
// is fine because we always immediately exec() after fork(), and exec()
// clobbers all process state. Also, we don't want the sampler to resume in the
// child process between fork() and exec(), it would be wasteful.
//
// Unfortunately all this is only doable on non-Android because Bionic doesn't
// have pthread_atfork.

// In the parent, before the fork, increase gSkipSampling to ensure that
// profiler sampling loops will be skipped. There could be one in progress now,
// causing a small delay, but further sampling will be skipped, allowing `fork`
// to complete.
static void paf_prepare() { ++gSkipSampling; }

// In the parent, after the fork, decrease gSkipSampling to let the sampler
// resume sampling (unless other places have made it non-zero as well).
static void paf_parent() { --gSkipSampling; }

static void PlatformInit(PSLockRef aLock) {
  // Set up the fork handlers.
  pthread_atfork(paf_prepare, paf_parent, nullptr);
}

#else

static void PlatformInit(PSLockRef aLock) {}

#endif

#if defined(HAVE_NATIVE_UNWIND)
void Registers::SyncPopulate() {
  if (!getcontext(&mContextSyncStorage)) {
    PopulateRegsFromContext(*this, &mContextSyncStorage);
  }
}
#endif