blob: cc7cbe5f05c1e417be4047c5a2795b649cd70b29 [file] [log] [blame]
// Copyright 2006-2008 the V8 project 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.
// Platform specific code for Linux goes here. For the POSIX comaptible parts
// the implementation is in platform-posix.cc.
#include <pthread.h>
#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>
// 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
#ifdef __GLIBC__
#include <execinfo.h> // backtrace, backtrace_symbols
#endif // def __GLIBC__
#include <strings.h> // index
#include <errno.h>
#include <stdarg.h>
#undef MAP_TYPE
#include "v8.h"
#include "platform.h"
#include "top.h"
#include "v8threads.h"
namespace v8 {
namespace internal {
// 0 is never a valid thread id on Linux since tids and pids share a
// name space and pid 0 is reserved (see man 2 kill).
static const pthread_t kNoThread = (pthread_t) 0;
double ceiling(double x) {
return ceil(x);
}
void OS::Setup() {
// Seed the random number generator.
// Convert the current time to a 64-bit integer first, before converting it
// to an unsigned. Going directly can cause an overflow and the seed to be
// set to all ones. The seed will be identical for different instances that
// call this setup code within the same millisecond.
uint64_t seed = static_cast<uint64_t>(TimeCurrentMillis());
srandom(static_cast<unsigned int>(seed));
}
uint64_t OS::CpuFeaturesImpliedByPlatform() {
#if (defined(__VFP_FP__) && !defined(__SOFTFP__))
// Here gcc is telling us that we are on an ARM and gcc is assuming that we
// have VFP3 instructions. If gcc can assume it then so can we.
return 1u << VFP3;
#elif CAN_USE_ARMV7_INSTRUCTIONS
return 1u << ARMv7;
#else
return 0; // Linux runs on anything.
#endif
}
#ifdef __arm__
static bool CPUInfoContainsString(const char * search_string) {
const char* file_name = "/proc/cpuinfo";
// This is written as a straight shot one pass parser
// and not using STL string and ifstream because,
// on Linux, it's reading from a (non-mmap-able)
// character special device.
FILE* f = NULL;
const char* what = search_string;
if (NULL == (f = fopen(file_name, "r")))
return false;
int k;
while (EOF != (k = fgetc(f))) {
if (k == *what) {
++what;
while ((*what != '\0') && (*what == fgetc(f))) {
++what;
}
if (*what == '\0') {
fclose(f);
return true;
} else {
what = search_string;
}
}
}
fclose(f);
// Did not find string in the proc file.
return false;
}
bool OS::ArmCpuHasFeature(CpuFeature feature) {
const char* search_string = NULL;
// Simple detection of VFP at runtime for Linux.
// It is based on /proc/cpuinfo, which reveals hardware configuration
// to user-space applications. According to ARM (mid 2009), no similar
// facility is universally available on the ARM architectures,
// so it's up to individual OSes to provide such.
switch (feature) {
case VFP3:
search_string = "vfpv3";
break;
case ARMv7:
search_string = "ARMv7";
break;
default:
UNREACHABLE();
}
if (CPUInfoContainsString(search_string)) {
return true;
}
if (feature == VFP3) {
// Some old kernels will report vfp not vfpv3. Here we make a last attempt
// to detect vfpv3 by checking for vfp *and* neon, since neon is only
// available on architectures with vfpv3.
// Checking neon on its own is not enough as it is possible to have neon
// without vfp.
if (CPUInfoContainsString("vfp") && CPUInfoContainsString("neon")) {
return true;
}
}
return false;
}
#endif // def __arm__
int OS::ActivationFrameAlignment() {
#ifdef V8_TARGET_ARCH_ARM
// On EABI ARM targets this is required for fp correctness in the
// runtime system.
return 8;
#elif V8_TARGET_ARCH_MIPS
return 8;
#endif
// With gcc 4.4 the tree vectorization optimizer can generate code
// that requires 16 byte alignment such as movdqa on x86.
return 16;
}
#ifdef V8_TARGET_ARCH_ARM
// 0xffff0fa0 is the hard coded address of a function provided by
// the kernel which implements a memory barrier. On older
// ARM architecture revisions (pre-v6) this may be implemented using
// a syscall. This address is stable, and in active use (hard coded)
// by at least glibc-2.7 and the Android C library.
typedef void (*LinuxKernelMemoryBarrierFunc)(void);
LinuxKernelMemoryBarrierFunc pLinuxKernelMemoryBarrier __attribute__((weak)) =
(LinuxKernelMemoryBarrierFunc) 0xffff0fa0;
#endif
void OS::ReleaseStore(volatile AtomicWord* ptr, AtomicWord value) {
#if defined(V8_TARGET_ARCH_ARM) && defined(__arm__)
// Only use on ARM hardware.
pLinuxKernelMemoryBarrier();
#else
__asm__ __volatile__("" : : : "memory");
// An x86 store acts as a release barrier.
#endif
*ptr = value;
}
const char* OS::LocalTimezone(double time) {
if (isnan(time)) return "";
time_t tv = static_cast<time_t>(floor(time/msPerSecond));
struct tm* t = localtime(&tv);
if (NULL == t) return "";
return t->tm_zone;
}
double OS::LocalTimeOffset() {
time_t tv = time(NULL);
struct tm* t = localtime(&tv);
// tm_gmtoff includes any daylight savings offset, so subtract it.
return static_cast<double>(t->tm_gmtoff * msPerSecond -
(t->tm_isdst > 0 ? 3600 * msPerSecond : 0));
}
// We keep the lowest and highest addresses mapped as a quick way of
// determining that pointers are outside the heap (used mostly in assertions
// and verification). The estimate is conservative, ie, not all addresses in
// 'allocated' space are actually allocated to our heap. The range is
// [lowest, highest), inclusive on the low and and exclusive on the high end.
static void* lowest_ever_allocated = reinterpret_cast<void*>(-1);
static void* highest_ever_allocated = reinterpret_cast<void*>(0);
static void UpdateAllocatedSpaceLimits(void* address, int size) {
lowest_ever_allocated = Min(lowest_ever_allocated, address);
highest_ever_allocated =
Max(highest_ever_allocated,
reinterpret_cast<void*>(reinterpret_cast<char*>(address) + size));
}
bool OS::IsOutsideAllocatedSpace(void* address) {
return address < lowest_ever_allocated || address >= highest_ever_allocated;
}
size_t OS::AllocateAlignment() {
return sysconf(_SC_PAGESIZE);
}
void* OS::Allocate(const size_t requested,
size_t* allocated,
bool is_executable) {
// TODO(805): Port randomization of allocated executable memory to Linux.
const size_t msize = RoundUp(requested, sysconf(_SC_PAGESIZE));
int prot = PROT_READ | PROT_WRITE | (is_executable ? PROT_EXEC : 0);
void* mbase = mmap(NULL, msize, prot, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
if (mbase == MAP_FAILED) {
LOG(StringEvent("OS::Allocate", "mmap failed"));
return NULL;
}
*allocated = msize;
UpdateAllocatedSpaceLimits(mbase, msize);
return mbase;
}
void OS::Free(void* address, const size_t size) {
// TODO(1240712): munmap has a return value which is ignored here.
int result = munmap(address, size);
USE(result);
ASSERT(result == 0);
}
#ifdef ENABLE_HEAP_PROTECTION
void OS::Protect(void* address, size_t size) {
// TODO(1240712): mprotect has a return value which is ignored here.
mprotect(address, size, PROT_READ);
}
void OS::Unprotect(void* address, size_t size, bool is_executable) {
// TODO(1240712): mprotect has a return value which is ignored here.
int prot = PROT_READ | PROT_WRITE | (is_executable ? PROT_EXEC : 0);
mprotect(address, size, prot);
}
#endif
void OS::Sleep(int milliseconds) {
unsigned int ms = static_cast<unsigned int>(milliseconds);
usleep(1000 * ms);
}
void OS::Abort() {
// Redirect to std abort to signal abnormal program termination.
abort();
}
void OS::DebugBreak() {
// TODO(lrn): Introduce processor define for runtime system (!= V8_ARCH_x,
// which is the architecture of generated code).
#if (defined(__arm__) || defined(__thumb__))
# if defined(CAN_USE_ARMV5_INSTRUCTIONS)
asm("bkpt 0");
# endif
#elif defined(__mips__)
asm("break");
#else
asm("int $3");
#endif
}
class PosixMemoryMappedFile : public OS::MemoryMappedFile {
public:
PosixMemoryMappedFile(FILE* file, void* memory, int size)
: file_(file), memory_(memory), size_(size) { }
virtual ~PosixMemoryMappedFile();
virtual void* memory() { return memory_; }
private:
FILE* file_;
void* memory_;
int size_;
};
OS::MemoryMappedFile* OS::MemoryMappedFile::create(const char* name, int size,
void* initial) {
FILE* file = fopen(name, "w+");
if (file == NULL) return NULL;
int result = fwrite(initial, size, 1, file);
if (result < 1) {
fclose(file);
return NULL;
}
void* memory =
mmap(0, size, PROT_READ | PROT_WRITE, MAP_SHARED, fileno(file), 0);
return new PosixMemoryMappedFile(file, memory, size);
}
PosixMemoryMappedFile::~PosixMemoryMappedFile() {
if (memory_) munmap(memory_, size_);
fclose(file_);
}
void OS::LogSharedLibraryAddresses() {
#ifdef ENABLE_LOGGING_AND_PROFILING
// This function assumes that the layout of the file is as follows:
// hex_start_addr-hex_end_addr rwxp <unused data> [binary_file_name]
// If we encounter an unexpected situation we abort scanning further entries.
FILE* fp = fopen("/proc/self/maps", "r");
if (fp == NULL) return;
// Allocate enough room to be able to store a full file name.
const int kLibNameLen = FILENAME_MAX + 1;
char* lib_name = reinterpret_cast<char*>(malloc(kLibNameLen));
// This loop will terminate once the scanning hits an EOF.
while (true) {
uintptr_t start, end;
char attr_r, attr_w, attr_x, attr_p;
// Parse the addresses and permission bits at the beginning of the line.
if (fscanf(fp, "%" V8PRIxPTR "-%" V8PRIxPTR, &start, &end) != 2) break;
if (fscanf(fp, " %c%c%c%c", &attr_r, &attr_w, &attr_x, &attr_p) != 4) break;
int c;
if (attr_r == 'r' && attr_w != 'w' && attr_x == 'x') {
// Found a read-only executable entry. Skip characters until we reach
// the beginning of the filename or the end of the line.
do {
c = getc(fp);
} while ((c != EOF) && (c != '\n') && (c != '/'));
if (c == EOF) break; // EOF: Was unexpected, just exit.
// Process the filename if found.
if (c == '/') {
ungetc(c, fp); // Push the '/' back into the stream to be read below.
// Read to the end of the line. Exit if the read fails.
if (fgets(lib_name, kLibNameLen, fp) == NULL) break;
// Drop the newline character read by fgets. We do not need to check
// for a zero-length string because we know that we at least read the
// '/' character.
lib_name[strlen(lib_name) - 1] = '\0';
} else {
// No library name found, just record the raw address range.
snprintf(lib_name, kLibNameLen,
"%08" V8PRIxPTR "-%08" V8PRIxPTR, start, end);
}
LOG(SharedLibraryEvent(lib_name, start, end));
} else {
// Entry not describing executable data. Skip to end of line to setup
// reading the next entry.
do {
c = getc(fp);
} while ((c != EOF) && (c != '\n'));
if (c == EOF) break;
}
}
free(lib_name);
fclose(fp);
#endif
}
static const char kGCFakeMmap[] = "/tmp/__v8_gc__";
void OS::SignalCodeMovingGC() {
#ifdef ENABLE_LOGGING_AND_PROFILING
// Support for ll_prof.py.
//
// The Linux profiler built into the kernel logs all mmap's with
// PROT_EXEC so that analysis tools can properly attribute ticks. We
// do a mmap with a name known by ll_prof.py and immediately munmap
// it. This injects a GC marker into the stream of events generated
// by the kernel and allows us to synchronize V8 code log and the
// kernel log.
int size = sysconf(_SC_PAGESIZE);
FILE* f = fopen(kGCFakeMmap, "w+");
void* addr = mmap(NULL, size, PROT_READ | PROT_EXEC, MAP_PRIVATE,
fileno(f), 0);
ASSERT(addr != MAP_FAILED);
munmap(addr, size);
fclose(f);
#endif
}
int OS::StackWalk(Vector<OS::StackFrame> frames) {
// backtrace is a glibc extension.
#ifdef __GLIBC__
int frames_size = frames.length();
ScopedVector<void*> addresses(frames_size);
int frames_count = backtrace(addresses.start(), frames_size);
char** symbols = backtrace_symbols(addresses.start(), frames_count);
if (symbols == NULL) {
return kStackWalkError;
}
for (int i = 0; i < frames_count; i++) {
frames[i].address = addresses[i];
// Format a text representation of the frame based on the information
// available.
SNPrintF(MutableCStrVector(frames[i].text, kStackWalkMaxTextLen),
"%s",
symbols[i]);
// Make sure line termination is in place.
frames[i].text[kStackWalkMaxTextLen - 1] = '\0';
}
free(symbols);
return frames_count;
#else // ndef __GLIBC__
return 0;
#endif // ndef __GLIBC__
}
// Constants used for mmap.
static const int kMmapFd = -1;
static const int kMmapFdOffset = 0;
VirtualMemory::VirtualMemory(size_t size) {
address_ = mmap(NULL, size, PROT_NONE,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE,
kMmapFd, kMmapFdOffset);
size_ = size;
}
VirtualMemory::~VirtualMemory() {
if (IsReserved()) {
if (0 == munmap(address(), size())) address_ = MAP_FAILED;
}
}
bool VirtualMemory::IsReserved() {
return address_ != MAP_FAILED;
}
bool VirtualMemory::Commit(void* address, size_t size, bool is_executable) {
int prot = PROT_READ | PROT_WRITE | (is_executable ? PROT_EXEC : 0);
if (MAP_FAILED == mmap(address, size, prot,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED,
kMmapFd, kMmapFdOffset)) {
return false;
}
UpdateAllocatedSpaceLimits(address, size);
return true;
}
bool VirtualMemory::Uncommit(void* address, size_t size) {
return mmap(address, size, PROT_NONE,
MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE | MAP_FIXED,
kMmapFd, kMmapFdOffset) != MAP_FAILED;
}
class ThreadHandle::PlatformData : public Malloced {
public:
explicit PlatformData(ThreadHandle::Kind kind) {
Initialize(kind);
}
void Initialize(ThreadHandle::Kind kind) {
switch (kind) {
case ThreadHandle::SELF: thread_ = pthread_self(); break;
case ThreadHandle::INVALID: thread_ = kNoThread; break;
}
}
pthread_t thread_; // Thread handle for pthread.
};
ThreadHandle::ThreadHandle(Kind kind) {
data_ = new PlatformData(kind);
}
void ThreadHandle::Initialize(ThreadHandle::Kind kind) {
data_->Initialize(kind);
}
ThreadHandle::~ThreadHandle() {
delete data_;
}
bool ThreadHandle::IsSelf() const {
return pthread_equal(data_->thread_, pthread_self());
}
bool ThreadHandle::IsValid() const {
return data_->thread_ != kNoThread;
}
Thread::Thread() : ThreadHandle(ThreadHandle::INVALID) {
}
Thread::~Thread() {
}
static void* ThreadEntry(void* arg) {
Thread* thread = reinterpret_cast<Thread*>(arg);
// This is also initialized by the first argument to pthread_create() but we
// don't know which thread will run first (the original thread or the new
// one) so we initialize it here too.
thread->thread_handle_data()->thread_ = pthread_self();
ASSERT(thread->IsValid());
thread->Run();
return NULL;
}
void Thread::Start() {
pthread_create(&thread_handle_data()->thread_, NULL, ThreadEntry, this);
ASSERT(IsValid());
}
void Thread::Join() {
pthread_join(thread_handle_data()->thread_, NULL);
}
Thread::LocalStorageKey Thread::CreateThreadLocalKey() {
pthread_key_t key;
int result = pthread_key_create(&key, NULL);
USE(result);
ASSERT(result == 0);
return static_cast<LocalStorageKey>(key);
}
void Thread::DeleteThreadLocalKey(LocalStorageKey key) {
pthread_key_t pthread_key = static_cast<pthread_key_t>(key);
int result = pthread_key_delete(pthread_key);
USE(result);
ASSERT(result == 0);
}
void* Thread::GetThreadLocal(LocalStorageKey key) {
pthread_key_t pthread_key = static_cast<pthread_key_t>(key);
return pthread_getspecific(pthread_key);
}
void Thread::SetThreadLocal(LocalStorageKey key, void* value) {
pthread_key_t pthread_key = static_cast<pthread_key_t>(key);
pthread_setspecific(pthread_key, value);
}
void Thread::YieldCPU() {
sched_yield();
}
class LinuxMutex : public Mutex {
public:
LinuxMutex() {
pthread_mutexattr_t attrs;
int result = pthread_mutexattr_init(&attrs);
ASSERT(result == 0);
result = pthread_mutexattr_settype(&attrs, PTHREAD_MUTEX_RECURSIVE);
ASSERT(result == 0);
result = pthread_mutex_init(&mutex_, &attrs);
ASSERT(result == 0);
}
virtual ~LinuxMutex() { pthread_mutex_destroy(&mutex_); }
virtual int Lock() {
int result = pthread_mutex_lock(&mutex_);
return result;
}
virtual int Unlock() {
int result = pthread_mutex_unlock(&mutex_);
return result;
}
private:
pthread_mutex_t mutex_; // Pthread mutex for POSIX platforms.
};
Mutex* OS::CreateMutex() {
return new LinuxMutex();
}
class LinuxSemaphore : public Semaphore {
public:
explicit LinuxSemaphore(int count) { sem_init(&sem_, 0, count); }
virtual ~LinuxSemaphore() { sem_destroy(&sem_); }
virtual void Wait();
virtual bool Wait(int timeout);
virtual void Signal() { sem_post(&sem_); }
private:
sem_t sem_;
};
void LinuxSemaphore::Wait() {
while (true) {
int result = sem_wait(&sem_);
if (result == 0) return; // Successfully got semaphore.
CHECK(result == -1 && errno == EINTR); // Signal caused spurious wakeup.
}
}
#ifndef TIMEVAL_TO_TIMESPEC
#define TIMEVAL_TO_TIMESPEC(tv, ts) do { \
(ts)->tv_sec = (tv)->tv_sec; \
(ts)->tv_nsec = (tv)->tv_usec * 1000; \
} while (false)
#endif
bool LinuxSemaphore::Wait(int timeout) {
const long kOneSecondMicros = 1000000; // NOLINT
// Split timeout into second and nanosecond parts.
struct timeval delta;
delta.tv_usec = timeout % kOneSecondMicros;
delta.tv_sec = timeout / kOneSecondMicros;
struct timeval current_time;
// Get the current time.
if (gettimeofday(&current_time, NULL) == -1) {
return false;
}
// Calculate time for end of timeout.
struct timeval end_time;
timeradd(&current_time, &delta, &end_time);
struct timespec ts;
TIMEVAL_TO_TIMESPEC(&end_time, &ts);
// Wait for semaphore signalled or timeout.
while (true) {
int result = sem_timedwait(&sem_, &ts);
if (result == 0) return true; // Successfully got semaphore.
if (result > 0) {
// For glibc prior to 2.3.4 sem_timedwait returns the error instead of -1.
errno = result;
result = -1;
}
if (result == -1 && errno == ETIMEDOUT) return false; // Timeout.
CHECK(result == -1 && errno == EINTR); // Signal caused spurious wakeup.
}
}
Semaphore* OS::CreateSemaphore(int count) {
return new LinuxSemaphore(count);
}
#ifdef ENABLE_LOGGING_AND_PROFILING
static Sampler* active_sampler_ = NULL;
#if !defined(__GLIBC__) && (defined(__arm__) || defined(__thumb__))
// Android runs a fairly new Linux kernel, so signal info is there,
// but the C library doesn't have the structs defined.
struct sigcontext {
uint32_t trap_no;
uint32_t error_code;
uint32_t oldmask;
uint32_t gregs[16];
uint32_t arm_cpsr;
uint32_t fault_address;
};
typedef uint32_t __sigset_t;
typedef struct sigcontext mcontext_t;
typedef struct ucontext {
uint32_t uc_flags;
struct ucontext* uc_link;
stack_t uc_stack;
mcontext_t uc_mcontext;
__sigset_t uc_sigmask;
} ucontext_t;
enum ArmRegisters {R15 = 15, R13 = 13, R11 = 11};
#endif
static void ProfilerSignalHandler(int signal, siginfo_t* info, void* context) {
#ifndef V8_HOST_ARCH_MIPS
USE(info);
if (signal != SIGPROF) return;
if (active_sampler_ == NULL) return;
TickSample sample_obj;
TickSample* sample = CpuProfiler::TickSampleEvent();
if (sample == NULL) sample = &sample_obj;
// We always sample the VM state.
sample->state = VMState::current_state();
// If profiling, we extract the current pc and sp.
if (active_sampler_->IsProfiling()) {
// Extracting the sample from the context is extremely machine dependent.
ucontext_t* ucontext = reinterpret_cast<ucontext_t*>(context);
mcontext_t& mcontext = ucontext->uc_mcontext;
#if V8_HOST_ARCH_IA32
sample->pc = reinterpret_cast<Address>(mcontext.gregs[REG_EIP]);
sample->sp = reinterpret_cast<Address>(mcontext.gregs[REG_ESP]);
sample->fp = reinterpret_cast<Address>(mcontext.gregs[REG_EBP]);
#elif V8_HOST_ARCH_X64
sample->pc = reinterpret_cast<Address>(mcontext.gregs[REG_RIP]);
sample->sp = reinterpret_cast<Address>(mcontext.gregs[REG_RSP]);
sample->fp = reinterpret_cast<Address>(mcontext.gregs[REG_RBP]);
#elif V8_HOST_ARCH_ARM
// An undefined macro evaluates to 0, so this applies to Android's Bionic also.
#if (__GLIBC__ < 2 || (__GLIBC__ == 2 && __GLIBC_MINOR__ <= 3))
sample->pc = reinterpret_cast<Address>(mcontext.gregs[R15]);
sample->sp = reinterpret_cast<Address>(mcontext.gregs[R13]);
sample->fp = reinterpret_cast<Address>(mcontext.gregs[R11]);
#else
sample->pc = reinterpret_cast<Address>(mcontext.arm_pc);
sample->sp = reinterpret_cast<Address>(mcontext.arm_sp);
sample->fp = reinterpret_cast<Address>(mcontext.arm_fp);
#endif
#elif V8_HOST_ARCH_MIPS
// Implement this on MIPS.
UNIMPLEMENTED();
#endif
active_sampler_->SampleStack(sample);
}
active_sampler_->Tick(sample);
#endif
}
class Sampler::PlatformData : public Malloced {
public:
explicit PlatformData(Sampler* sampler)
: sampler_(sampler),
signal_handler_installed_(false),
vm_tgid_(getpid()),
// Glibc doesn't provide a wrapper for gettid(2).
vm_tid_(syscall(SYS_gettid)),
signal_sender_launched_(false) {
}
void SignalSender() {
while (sampler_->IsActive()) {
// Glibc doesn't provide a wrapper for tgkill(2).
syscall(SYS_tgkill, vm_tgid_, vm_tid_, SIGPROF);
// Convert ms to us and subtract 100 us to compensate delays
// occuring during signal delivery.
const useconds_t interval = sampler_->interval_ * 1000 - 100;
int result = usleep(interval);
#ifdef DEBUG
if (result != 0 && errno != EINTR) {
fprintf(stderr,
"SignalSender usleep error; interval = %u, errno = %d\n",
interval,
errno);
ASSERT(result == 0 || errno == EINTR);
}
#endif
USE(result);
}
}
Sampler* sampler_;
bool signal_handler_installed_;
struct sigaction old_signal_handler_;
int vm_tgid_;
int vm_tid_;
bool signal_sender_launched_;
pthread_t signal_sender_thread_;
};
static void* SenderEntry(void* arg) {
Sampler::PlatformData* data =
reinterpret_cast<Sampler::PlatformData*>(arg);
data->SignalSender();
return 0;
}
Sampler::Sampler(int interval, bool profiling)
: interval_(interval),
profiling_(profiling),
synchronous_(profiling),
active_(false),
samples_taken_(0) {
data_ = new PlatformData(this);
}
Sampler::~Sampler() {
ASSERT(!data_->signal_sender_launched_);
delete data_;
}
void Sampler::Start() {
// There can only be one active sampler at the time on POSIX
// platforms.
if (active_sampler_ != NULL) return;
// Request profiling signals.
struct sigaction sa;
sa.sa_sigaction = ProfilerSignalHandler;
sigemptyset(&sa.sa_mask);
sa.sa_flags = SA_RESTART | SA_SIGINFO;
if (sigaction(SIGPROF, &sa, &data_->old_signal_handler_) != 0) return;
data_->signal_handler_installed_ = true;
// Start a thread that sends SIGPROF signal to VM thread.
// Sending the signal ourselves instead of relying on itimer provides
// much better accuracy.
active_ = true;
if (pthread_create(
&data_->signal_sender_thread_, NULL, SenderEntry, data_) == 0) {
data_->signal_sender_launched_ = true;
}
// Set this sampler as the active sampler.
active_sampler_ = this;
}
void Sampler::Stop() {
active_ = false;
// Wait for signal sender termination (it will exit after setting
// active_ to false).
if (data_->signal_sender_launched_) {
pthread_join(data_->signal_sender_thread_, NULL);
data_->signal_sender_launched_ = false;
}
// Restore old signal handler
if (data_->signal_handler_installed_) {
sigaction(SIGPROF, &data_->old_signal_handler_, 0);
data_->signal_handler_installed_ = false;
}
// This sampler is no longer the active sampler.
active_sampler_ = NULL;
}
#endif // ENABLE_LOGGING_AND_PROFILING
} } // namespace v8::internal