blob: 3c7a71aba9dab8d2db0cdcb6d58b39fab9186173 [file] [log] [blame]
/*
* Copyright (C) 2011 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "thread.h"
#include <pthread.h>
#include <signal.h>
#include <sys/resource.h>
#include <sys/time.h>
#include <algorithm>
#include <bitset>
#include <cerrno>
#include <iostream>
#include <list>
#include <sstream>
#include "android-base/stringprintf.h"
#include "arch/context.h"
#include "art_field-inl.h"
#include "art_method-inl.h"
#include "base/bit_utils.h"
#include "base/memory_tool.h"
#include "base/mutex.h"
#include "base/timing_logger.h"
#include "base/to_str.h"
#include "base/systrace.h"
#include "class_linker-inl.h"
#include "debugger.h"
#include "dex_file-inl.h"
#include "dex_file_annotations.h"
#include "entrypoints/entrypoint_utils.h"
#include "entrypoints/quick/quick_alloc_entrypoints.h"
#include "gc/accounting/card_table-inl.h"
#include "gc/accounting/heap_bitmap-inl.h"
#include "gc/allocator/rosalloc.h"
#include "gc/heap.h"
#include "gc/space/space-inl.h"
#include "handle_scope-inl.h"
#include "indirect_reference_table-inl.h"
#include "jni_internal.h"
#include "mirror/class_loader.h"
#include "mirror/class-inl.h"
#include "mirror/object_array-inl.h"
#include "mirror/stack_trace_element.h"
#include "monitor.h"
#include "native_stack_dump.h"
#include "nth_caller_visitor.h"
#include "oat_quick_method_header.h"
#include "obj_ptr-inl.h"
#include "object_lock.h"
#include "quick_exception_handler.h"
#include "quick/quick_method_frame_info.h"
#include "reflection.h"
#include "runtime.h"
#include "runtime_callbacks.h"
#include "scoped_thread_state_change-inl.h"
#include "ScopedLocalRef.h"
#include "ScopedUtfChars.h"
#include "stack.h"
#include "stack_map.h"
#include "thread_list.h"
#include "thread-inl.h"
#include "utils.h"
#include "verifier/method_verifier.h"
#include "verify_object-inl.h"
#include "well_known_classes.h"
#include "interpreter/interpreter.h"
#if ART_USE_FUTEXES
#include "linux/futex.h"
#include "sys/syscall.h"
#ifndef SYS_futex
#define SYS_futex __NR_futex
#endif
#endif // ART_USE_FUTEXES
namespace art {
using android::base::StringAppendV;
using android::base::StringPrintf;
extern "C" NO_RETURN void artDeoptimize(Thread* self);
bool Thread::is_started_ = false;
pthread_key_t Thread::pthread_key_self_;
ConditionVariable* Thread::resume_cond_ = nullptr;
const size_t Thread::kStackOverflowImplicitCheckSize = GetStackOverflowReservedBytes(kRuntimeISA);
bool (*Thread::is_sensitive_thread_hook_)() = nullptr;
Thread* Thread::jit_sensitive_thread_ = nullptr;
static constexpr bool kVerifyImageObjectsMarked = kIsDebugBuild;
// For implicit overflow checks we reserve an extra piece of memory at the bottom
// of the stack (lowest memory). The higher portion of the memory
// is protected against reads and the lower is available for use while
// throwing the StackOverflow exception.
constexpr size_t kStackOverflowProtectedSize = 4 * kMemoryToolStackGuardSizeScale * KB;
static const char* kThreadNameDuringStartup = "<native thread without managed peer>";
void Thread::InitCardTable() {
tlsPtr_.card_table = Runtime::Current()->GetHeap()->GetCardTable()->GetBiasedBegin();
}
static void UnimplementedEntryPoint() {
UNIMPLEMENTED(FATAL);
}
void InitEntryPoints(JniEntryPoints* jpoints, QuickEntryPoints* qpoints);
void UpdateReadBarrierEntrypoints(QuickEntryPoints* qpoints, bool is_marking);
void Thread::SetIsGcMarkingAndUpdateEntrypoints(bool is_marking) {
CHECK(kUseReadBarrier);
tls32_.is_gc_marking = is_marking;
UpdateReadBarrierEntrypoints(&tlsPtr_.quick_entrypoints, is_marking);
ResetQuickAllocEntryPointsForThread(is_marking);
}
void Thread::InitTlsEntryPoints() {
// Insert a placeholder so we can easily tell if we call an unimplemented entry point.
uintptr_t* begin = reinterpret_cast<uintptr_t*>(&tlsPtr_.jni_entrypoints);
uintptr_t* end = reinterpret_cast<uintptr_t*>(
reinterpret_cast<uint8_t*>(&tlsPtr_.quick_entrypoints) + sizeof(tlsPtr_.quick_entrypoints));
for (uintptr_t* it = begin; it != end; ++it) {
*it = reinterpret_cast<uintptr_t>(UnimplementedEntryPoint);
}
InitEntryPoints(&tlsPtr_.jni_entrypoints, &tlsPtr_.quick_entrypoints);
}
void Thread::ResetQuickAllocEntryPointsForThread(bool is_marking) {
if (kUseReadBarrier && kRuntimeISA != kX86_64) {
// Allocation entrypoint switching is currently only implemented for X86_64.
is_marking = true;
}
ResetQuickAllocEntryPoints(&tlsPtr_.quick_entrypoints, is_marking);
}
class DeoptimizationContextRecord {
public:
DeoptimizationContextRecord(const JValue& ret_val,
bool is_reference,
bool from_code,
ObjPtr<mirror::Throwable> pending_exception,
DeoptimizationContextRecord* link)
: ret_val_(ret_val),
is_reference_(is_reference),
from_code_(from_code),
pending_exception_(pending_exception.Ptr()),
link_(link) {}
JValue GetReturnValue() const { return ret_val_; }
bool IsReference() const { return is_reference_; }
bool GetFromCode() const { return from_code_; }
ObjPtr<mirror::Throwable> GetPendingException() const { return pending_exception_; }
DeoptimizationContextRecord* GetLink() const { return link_; }
mirror::Object** GetReturnValueAsGCRoot() {
DCHECK(is_reference_);
return ret_val_.GetGCRoot();
}
mirror::Object** GetPendingExceptionAsGCRoot() {
return reinterpret_cast<mirror::Object**>(&pending_exception_);
}
private:
// The value returned by the method at the top of the stack before deoptimization.
JValue ret_val_;
// Indicates whether the returned value is a reference. If so, the GC will visit it.
const bool is_reference_;
// Whether the context was created from an explicit deoptimization in the code.
const bool from_code_;
// The exception that was pending before deoptimization (or null if there was no pending
// exception).
mirror::Throwable* pending_exception_;
// A link to the previous DeoptimizationContextRecord.
DeoptimizationContextRecord* const link_;
DISALLOW_COPY_AND_ASSIGN(DeoptimizationContextRecord);
};
class StackedShadowFrameRecord {
public:
StackedShadowFrameRecord(ShadowFrame* shadow_frame,
StackedShadowFrameType type,
StackedShadowFrameRecord* link)
: shadow_frame_(shadow_frame),
type_(type),
link_(link) {}
ShadowFrame* GetShadowFrame() const { return shadow_frame_; }
StackedShadowFrameType GetType() const { return type_; }
StackedShadowFrameRecord* GetLink() const { return link_; }
private:
ShadowFrame* const shadow_frame_;
const StackedShadowFrameType type_;
StackedShadowFrameRecord* const link_;
DISALLOW_COPY_AND_ASSIGN(StackedShadowFrameRecord);
};
void Thread::PushDeoptimizationContext(const JValue& return_value,
bool is_reference,
bool from_code,
ObjPtr<mirror::Throwable> exception) {
DeoptimizationContextRecord* record = new DeoptimizationContextRecord(
return_value,
is_reference,
from_code,
exception,
tlsPtr_.deoptimization_context_stack);
tlsPtr_.deoptimization_context_stack = record;
}
void Thread::PopDeoptimizationContext(JValue* result,
ObjPtr<mirror::Throwable>* exception,
bool* from_code) {
AssertHasDeoptimizationContext();
DeoptimizationContextRecord* record = tlsPtr_.deoptimization_context_stack;
tlsPtr_.deoptimization_context_stack = record->GetLink();
result->SetJ(record->GetReturnValue().GetJ());
*exception = record->GetPendingException();
*from_code = record->GetFromCode();
delete record;
}
void Thread::AssertHasDeoptimizationContext() {
CHECK(tlsPtr_.deoptimization_context_stack != nullptr)
<< "No deoptimization context for thread " << *this;
}
void Thread::PushStackedShadowFrame(ShadowFrame* sf, StackedShadowFrameType type) {
StackedShadowFrameRecord* record = new StackedShadowFrameRecord(
sf, type, tlsPtr_.stacked_shadow_frame_record);
tlsPtr_.stacked_shadow_frame_record = record;
}
ShadowFrame* Thread::PopStackedShadowFrame(StackedShadowFrameType type, bool must_be_present) {
StackedShadowFrameRecord* record = tlsPtr_.stacked_shadow_frame_record;
if (must_be_present) {
DCHECK(record != nullptr);
} else {
if (record == nullptr || record->GetType() != type) {
return nullptr;
}
}
tlsPtr_.stacked_shadow_frame_record = record->GetLink();
ShadowFrame* shadow_frame = record->GetShadowFrame();
delete record;
return shadow_frame;
}
class FrameIdToShadowFrame {
public:
static FrameIdToShadowFrame* Create(size_t frame_id,
ShadowFrame* shadow_frame,
FrameIdToShadowFrame* next,
size_t num_vregs) {
// Append a bool array at the end to keep track of what vregs are updated by the debugger.
uint8_t* memory = new uint8_t[sizeof(FrameIdToShadowFrame) + sizeof(bool) * num_vregs];
return new (memory) FrameIdToShadowFrame(frame_id, shadow_frame, next);
}
static void Delete(FrameIdToShadowFrame* f) {
uint8_t* memory = reinterpret_cast<uint8_t*>(f);
delete[] memory;
}
size_t GetFrameId() const { return frame_id_; }
ShadowFrame* GetShadowFrame() const { return shadow_frame_; }
FrameIdToShadowFrame* GetNext() const { return next_; }
void SetNext(FrameIdToShadowFrame* next) { next_ = next; }
bool* GetUpdatedVRegFlags() {
return updated_vreg_flags_;
}
private:
FrameIdToShadowFrame(size_t frame_id,
ShadowFrame* shadow_frame,
FrameIdToShadowFrame* next)
: frame_id_(frame_id),
shadow_frame_(shadow_frame),
next_(next) {}
const size_t frame_id_;
ShadowFrame* const shadow_frame_;
FrameIdToShadowFrame* next_;
bool updated_vreg_flags_[0];
DISALLOW_COPY_AND_ASSIGN(FrameIdToShadowFrame);
};
static FrameIdToShadowFrame* FindFrameIdToShadowFrame(FrameIdToShadowFrame* head,
size_t frame_id) {
FrameIdToShadowFrame* found = nullptr;
for (FrameIdToShadowFrame* record = head; record != nullptr; record = record->GetNext()) {
if (record->GetFrameId() == frame_id) {
if (kIsDebugBuild) {
// Sanity check we have at most one record for this frame.
CHECK(found == nullptr) << "Multiple records for the frame " << frame_id;
found = record;
} else {
return record;
}
}
}
return found;
}
ShadowFrame* Thread::FindDebuggerShadowFrame(size_t frame_id) {
FrameIdToShadowFrame* record = FindFrameIdToShadowFrame(
tlsPtr_.frame_id_to_shadow_frame, frame_id);
if (record != nullptr) {
return record->GetShadowFrame();
}
return nullptr;
}
// Must only be called when FindDebuggerShadowFrame(frame_id) returns non-nullptr.
bool* Thread::GetUpdatedVRegFlags(size_t frame_id) {
FrameIdToShadowFrame* record = FindFrameIdToShadowFrame(
tlsPtr_.frame_id_to_shadow_frame, frame_id);
CHECK(record != nullptr);
return record->GetUpdatedVRegFlags();
}
ShadowFrame* Thread::FindOrCreateDebuggerShadowFrame(size_t frame_id,
uint32_t num_vregs,
ArtMethod* method,
uint32_t dex_pc) {
ShadowFrame* shadow_frame = FindDebuggerShadowFrame(frame_id);
if (shadow_frame != nullptr) {
return shadow_frame;
}
VLOG(deopt) << "Create pre-deopted ShadowFrame for " << ArtMethod::PrettyMethod(method);
shadow_frame = ShadowFrame::CreateDeoptimizedFrame(num_vregs, nullptr, method, dex_pc);
FrameIdToShadowFrame* record = FrameIdToShadowFrame::Create(frame_id,
shadow_frame,
tlsPtr_.frame_id_to_shadow_frame,
num_vregs);
for (uint32_t i = 0; i < num_vregs; i++) {
// Do this to clear all references for root visitors.
shadow_frame->SetVRegReference(i, nullptr);
// This flag will be changed to true if the debugger modifies the value.
record->GetUpdatedVRegFlags()[i] = false;
}
tlsPtr_.frame_id_to_shadow_frame = record;
return shadow_frame;
}
void Thread::RemoveDebuggerShadowFrameMapping(size_t frame_id) {
FrameIdToShadowFrame* head = tlsPtr_.frame_id_to_shadow_frame;
if (head->GetFrameId() == frame_id) {
tlsPtr_.frame_id_to_shadow_frame = head->GetNext();
FrameIdToShadowFrame::Delete(head);
return;
}
FrameIdToShadowFrame* prev = head;
for (FrameIdToShadowFrame* record = head->GetNext();
record != nullptr;
prev = record, record = record->GetNext()) {
if (record->GetFrameId() == frame_id) {
prev->SetNext(record->GetNext());
FrameIdToShadowFrame::Delete(record);
return;
}
}
LOG(FATAL) << "No shadow frame for frame " << frame_id;
UNREACHABLE();
}
void Thread::InitTid() {
tls32_.tid = ::art::GetTid();
}
void Thread::InitAfterFork() {
// One thread (us) survived the fork, but we have a new tid so we need to
// update the value stashed in this Thread*.
InitTid();
}
void* Thread::CreateCallback(void* arg) {
Thread* self = reinterpret_cast<Thread*>(arg);
Runtime* runtime = Runtime::Current();
if (runtime == nullptr) {
LOG(ERROR) << "Thread attaching to non-existent runtime: " << *self;
return nullptr;
}
{
// TODO: pass self to MutexLock - requires self to equal Thread::Current(), which is only true
// after self->Init().
MutexLock mu(nullptr, *Locks::runtime_shutdown_lock_);
// Check that if we got here we cannot be shutting down (as shutdown should never have started
// while threads are being born).
CHECK(!runtime->IsShuttingDownLocked());
// Note: given that the JNIEnv is created in the parent thread, the only failure point here is
// a mess in InitStackHwm. We do not have a reasonable way to recover from that, so abort
// the runtime in such a case. In case this ever changes, we need to make sure here to
// delete the tmp_jni_env, as we own it at this point.
CHECK(self->Init(runtime->GetThreadList(), runtime->GetJavaVM(), self->tlsPtr_.tmp_jni_env));
self->tlsPtr_.tmp_jni_env = nullptr;
Runtime::Current()->EndThreadBirth();
}
{
ScopedObjectAccess soa(self);
self->InitStringEntryPoints();
// Copy peer into self, deleting global reference when done.
CHECK(self->tlsPtr_.jpeer != nullptr);
self->tlsPtr_.opeer = soa.Decode<mirror::Object>(self->tlsPtr_.jpeer).Ptr();
self->GetJniEnv()->DeleteGlobalRef(self->tlsPtr_.jpeer);
self->tlsPtr_.jpeer = nullptr;
self->SetThreadName(self->GetThreadName()->ToModifiedUtf8().c_str());
ArtField* priorityField = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_priority);
self->SetNativePriority(priorityField->GetInt(self->tlsPtr_.opeer));
runtime->GetRuntimeCallbacks()->ThreadStart(self);
// Invoke the 'run' method of our java.lang.Thread.
ObjPtr<mirror::Object> receiver = self->tlsPtr_.opeer;
jmethodID mid = WellKnownClasses::java_lang_Thread_run;
ScopedLocalRef<jobject> ref(soa.Env(), soa.AddLocalReference<jobject>(receiver));
InvokeVirtualOrInterfaceWithJValues(soa, ref.get(), mid, nullptr);
}
// Detach and delete self.
Runtime::Current()->GetThreadList()->Unregister(self);
return nullptr;
}
Thread* Thread::FromManagedThread(const ScopedObjectAccessAlreadyRunnable& soa,
ObjPtr<mirror::Object> thread_peer) {
ArtField* f = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_nativePeer);
Thread* result = reinterpret_cast<Thread*>(static_cast<uintptr_t>(f->GetLong(thread_peer)));
// Sanity check that if we have a result it is either suspended or we hold the thread_list_lock_
// to stop it from going away.
if (kIsDebugBuild) {
MutexLock mu(soa.Self(), *Locks::thread_suspend_count_lock_);
if (result != nullptr && !result->IsSuspended()) {
Locks::thread_list_lock_->AssertHeld(soa.Self());
}
}
return result;
}
Thread* Thread::FromManagedThread(const ScopedObjectAccessAlreadyRunnable& soa,
jobject java_thread) {
return FromManagedThread(soa, soa.Decode<mirror::Object>(java_thread).Ptr());
}
static size_t FixStackSize(size_t stack_size) {
// A stack size of zero means "use the default".
if (stack_size == 0) {
stack_size = Runtime::Current()->GetDefaultStackSize();
}
// Dalvik used the bionic pthread default stack size for native threads,
// so include that here to support apps that expect large native stacks.
stack_size += 1 * MB;
// It's not possible to request a stack smaller than the system-defined PTHREAD_STACK_MIN.
if (stack_size < PTHREAD_STACK_MIN) {
stack_size = PTHREAD_STACK_MIN;
}
if (Runtime::Current()->ExplicitStackOverflowChecks()) {
// It's likely that callers are trying to ensure they have at least a certain amount of
// stack space, so we should add our reserved space on top of what they requested, rather
// than implicitly take it away from them.
stack_size += GetStackOverflowReservedBytes(kRuntimeISA);
} else {
// If we are going to use implicit stack checks, allocate space for the protected
// region at the bottom of the stack.
stack_size += Thread::kStackOverflowImplicitCheckSize +
GetStackOverflowReservedBytes(kRuntimeISA);
}
// Some systems require the stack size to be a multiple of the system page size, so round up.
stack_size = RoundUp(stack_size, kPageSize);
return stack_size;
}
// Return the nearest page-aligned address below the current stack top.
NO_INLINE
static uint8_t* FindStackTop() {
return reinterpret_cast<uint8_t*>(
AlignDown(__builtin_frame_address(0), kPageSize));
}
// Install a protected region in the stack. This is used to trigger a SIGSEGV if a stack
// overflow is detected. It is located right below the stack_begin_.
ATTRIBUTE_NO_SANITIZE_ADDRESS
void Thread::InstallImplicitProtection() {
uint8_t* pregion = tlsPtr_.stack_begin - kStackOverflowProtectedSize;
// Page containing current top of stack.
uint8_t* stack_top = FindStackTop();
// Try to directly protect the stack.
VLOG(threads) << "installing stack protected region at " << std::hex <<
static_cast<void*>(pregion) << " to " <<
static_cast<void*>(pregion + kStackOverflowProtectedSize - 1);
if (ProtectStack(/* fatal_on_error */ false)) {
// Tell the kernel that we won't be needing these pages any more.
// NB. madvise will probably write zeroes into the memory (on linux it does).
uint32_t unwanted_size = stack_top - pregion - kPageSize;
madvise(pregion, unwanted_size, MADV_DONTNEED);
return;
}
// There is a little complexity here that deserves a special mention. On some
// architectures, the stack is created using a VM_GROWSDOWN flag
// to prevent memory being allocated when it's not needed. This flag makes the
// kernel only allocate memory for the stack by growing down in memory. Because we
// want to put an mprotected region far away from that at the stack top, we need
// to make sure the pages for the stack are mapped in before we call mprotect.
//
// The failed mprotect in UnprotectStack is an indication of a thread with VM_GROWSDOWN
// with a non-mapped stack (usually only the main thread).
//
// We map in the stack by reading every page from the stack bottom (highest address)
// to the stack top. (We then madvise this away.) This must be done by reading from the
// current stack pointer downwards. Any access more than a page below the current SP
// might cause a segv.
// TODO: This comment may be out of date. It seems possible to speed this up. As
// this is normally done once in the zygote on startup, ignore for now.
//
// AddressSanitizer does not like the part of this functions that reads every stack page.
// Looks a lot like an out-of-bounds access.
// (Defensively) first remove the protection on the protected region as will want to read
// and write it. Ignore errors.
UnprotectStack();
VLOG(threads) << "Need to map in stack for thread at " << std::hex <<
static_cast<void*>(pregion);
// Read every page from the high address to the low.
volatile uint8_t dont_optimize_this;
UNUSED(dont_optimize_this);
for (uint8_t* p = stack_top; p >= pregion; p -= kPageSize) {
dont_optimize_this = *p;
}
VLOG(threads) << "(again) installing stack protected region at " << std::hex <<
static_cast<void*>(pregion) << " to " <<
static_cast<void*>(pregion + kStackOverflowProtectedSize - 1);
// Protect the bottom of the stack to prevent read/write to it.
ProtectStack(/* fatal_on_error */ true);
// Tell the kernel that we won't be needing these pages any more.
// NB. madvise will probably write zeroes into the memory (on linux it does).
uint32_t unwanted_size = stack_top - pregion - kPageSize;
madvise(pregion, unwanted_size, MADV_DONTNEED);
}
void Thread::CreateNativeThread(JNIEnv* env, jobject java_peer, size_t stack_size, bool is_daemon) {
CHECK(java_peer != nullptr);
Thread* self = static_cast<JNIEnvExt*>(env)->self;
if (VLOG_IS_ON(threads)) {
ScopedObjectAccess soa(env);
ArtField* f = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_name);
ObjPtr<mirror::String> java_name =
f->GetObject(soa.Decode<mirror::Object>(java_peer))->AsString();
std::string thread_name;
if (java_name != nullptr) {
thread_name = java_name->ToModifiedUtf8();
} else {
thread_name = "(Unnamed)";
}
VLOG(threads) << "Creating native thread for " << thread_name;
self->Dump(LOG_STREAM(INFO));
}
Runtime* runtime = Runtime::Current();
// Atomically start the birth of the thread ensuring the runtime isn't shutting down.
bool thread_start_during_shutdown = false;
{
MutexLock mu(self, *Locks::runtime_shutdown_lock_);
if (runtime->IsShuttingDownLocked()) {
thread_start_during_shutdown = true;
} else {
runtime->StartThreadBirth();
}
}
if (thread_start_during_shutdown) {
ScopedLocalRef<jclass> error_class(env, env->FindClass("java/lang/InternalError"));
env->ThrowNew(error_class.get(), "Thread starting during runtime shutdown");
return;
}
Thread* child_thread = new Thread(is_daemon);
// Use global JNI ref to hold peer live while child thread starts.
child_thread->tlsPtr_.jpeer = env->NewGlobalRef(java_peer);
stack_size = FixStackSize(stack_size);
// Thread.start is synchronized, so we know that nativePeer is 0, and know that we're not racing to
// assign it.
env->SetLongField(java_peer, WellKnownClasses::java_lang_Thread_nativePeer,
reinterpret_cast<jlong>(child_thread));
// Try to allocate a JNIEnvExt for the thread. We do this here as we might be out of memory and
// do not have a good way to report this on the child's side.
std::string error_msg;
std::unique_ptr<JNIEnvExt> child_jni_env_ext(
JNIEnvExt::Create(child_thread, Runtime::Current()->GetJavaVM(), &error_msg));
int pthread_create_result = 0;
if (child_jni_env_ext.get() != nullptr) {
pthread_t new_pthread;
pthread_attr_t attr;
child_thread->tlsPtr_.tmp_jni_env = child_jni_env_ext.get();
CHECK_PTHREAD_CALL(pthread_attr_init, (&attr), "new thread");
CHECK_PTHREAD_CALL(pthread_attr_setdetachstate, (&attr, PTHREAD_CREATE_DETACHED),
"PTHREAD_CREATE_DETACHED");
CHECK_PTHREAD_CALL(pthread_attr_setstacksize, (&attr, stack_size), stack_size);
pthread_create_result = pthread_create(&new_pthread,
&attr,
Thread::CreateCallback,
child_thread);
CHECK_PTHREAD_CALL(pthread_attr_destroy, (&attr), "new thread");
if (pthread_create_result == 0) {
// pthread_create started the new thread. The child is now responsible for managing the
// JNIEnvExt we created.
// Note: we can't check for tmp_jni_env == nullptr, as that would require synchronization
// between the threads.
child_jni_env_ext.release();
return;
}
}
// Either JNIEnvExt::Create or pthread_create(3) failed, so clean up.
{
MutexLock mu(self, *Locks::runtime_shutdown_lock_);
runtime->EndThreadBirth();
}
// Manually delete the global reference since Thread::Init will not have been run.
env->DeleteGlobalRef(child_thread->tlsPtr_.jpeer);
child_thread->tlsPtr_.jpeer = nullptr;
delete child_thread;
child_thread = nullptr;
// TODO: remove from thread group?
env->SetLongField(java_peer, WellKnownClasses::java_lang_Thread_nativePeer, 0);
{
std::string msg(child_jni_env_ext.get() == nullptr ?
StringPrintf("Could not allocate JNI Env: %s", error_msg.c_str()) :
StringPrintf("pthread_create (%s stack) failed: %s",
PrettySize(stack_size).c_str(), strerror(pthread_create_result)));
ScopedObjectAccess soa(env);
soa.Self()->ThrowOutOfMemoryError(msg.c_str());
}
}
bool Thread::Init(ThreadList* thread_list, JavaVMExt* java_vm, JNIEnvExt* jni_env_ext) {
// This function does all the initialization that must be run by the native thread it applies to.
// (When we create a new thread from managed code, we allocate the Thread* in Thread::Create so
// we can handshake with the corresponding native thread when it's ready.) Check this native
// thread hasn't been through here already...
CHECK(Thread::Current() == nullptr);
// Set pthread_self_ ahead of pthread_setspecific, that makes Thread::Current function, this
// avoids pthread_self_ ever being invalid when discovered from Thread::Current().
tlsPtr_.pthread_self = pthread_self();
CHECK(is_started_);
SetUpAlternateSignalStack();
if (!InitStackHwm()) {
return false;
}
InitCpu();
InitTlsEntryPoints();
RemoveSuspendTrigger();
InitCardTable();
InitTid();
interpreter::InitInterpreterTls(this);
#ifdef ART_TARGET_ANDROID
__get_tls()[TLS_SLOT_ART_THREAD_SELF] = this;
#else
CHECK_PTHREAD_CALL(pthread_setspecific, (Thread::pthread_key_self_, this), "attach self");
#endif
DCHECK_EQ(Thread::Current(), this);
tls32_.thin_lock_thread_id = thread_list->AllocThreadId(this);
if (jni_env_ext != nullptr) {
DCHECK_EQ(jni_env_ext->vm, java_vm);
DCHECK_EQ(jni_env_ext->self, this);
tlsPtr_.jni_env = jni_env_ext;
} else {
std::string error_msg;
tlsPtr_.jni_env = JNIEnvExt::Create(this, java_vm, &error_msg);
if (tlsPtr_.jni_env == nullptr) {
LOG(ERROR) << "Failed to create JNIEnvExt: " << error_msg;
return false;
}
}
thread_list->Register(this);
return true;
}
template <typename PeerAction>
Thread* Thread::Attach(const char* thread_name, bool as_daemon, PeerAction peer_action) {
Runtime* runtime = Runtime::Current();
if (runtime == nullptr) {
LOG(ERROR) << "Thread attaching to non-existent runtime: " << thread_name;
return nullptr;
}
Thread* self;
{
MutexLock mu(nullptr, *Locks::runtime_shutdown_lock_);
if (runtime->IsShuttingDownLocked()) {
LOG(WARNING) << "Thread attaching while runtime is shutting down: " << thread_name;
return nullptr;
} else {
Runtime::Current()->StartThreadBirth();
self = new Thread(as_daemon);
bool init_success = self->Init(runtime->GetThreadList(), runtime->GetJavaVM());
Runtime::Current()->EndThreadBirth();
if (!init_success) {
delete self;
return nullptr;
}
}
}
self->InitStringEntryPoints();
CHECK_NE(self->GetState(), kRunnable);
self->SetState(kNative);
// Run the action that is acting on the peer.
if (!peer_action(self)) {
runtime->GetThreadList()->Unregister(self);
// Unregister deletes self, no need to do this here.
return nullptr;
}
if (VLOG_IS_ON(threads)) {
if (thread_name != nullptr) {
VLOG(threads) << "Attaching thread " << thread_name;
} else {
VLOG(threads) << "Attaching unnamed thread.";
}
ScopedObjectAccess soa(self);
self->Dump(LOG_STREAM(INFO));
}
{
ScopedObjectAccess soa(self);
runtime->GetRuntimeCallbacks()->ThreadStart(self);
}
return self;
}
Thread* Thread::Attach(const char* thread_name,
bool as_daemon,
jobject thread_group,
bool create_peer) {
auto create_peer_action = [&](Thread* self) {
// If we're the main thread, ClassLinker won't be created until after we're attached,
// so that thread needs a two-stage attach. Regular threads don't need this hack.
// In the compiler, all threads need this hack, because no-one's going to be getting
// a native peer!
if (create_peer) {
self->CreatePeer(thread_name, as_daemon, thread_group);
if (self->IsExceptionPending()) {
// We cannot keep the exception around, as we're deleting self. Try to be helpful and log it.
{
ScopedObjectAccess soa(self);
LOG(ERROR) << "Exception creating thread peer:";
LOG(ERROR) << self->GetException()->Dump();
self->ClearException();
}
return false;
}
} else {
// These aren't necessary, but they improve diagnostics for unit tests & command-line tools.
if (thread_name != nullptr) {
self->tlsPtr_.name->assign(thread_name);
::art::SetThreadName(thread_name);
} else if (self->GetJniEnv()->check_jni) {
LOG(WARNING) << *Thread::Current() << " attached without supplying a name";
}
}
return true;
};
return Attach(thread_name, as_daemon, create_peer_action);
}
Thread* Thread::Attach(const char* thread_name, bool as_daemon, jobject thread_peer) {
auto set_peer_action = [&](Thread* self) {
// Install the given peer.
{
DCHECK(self == Thread::Current());
ScopedObjectAccess soa(self);
self->tlsPtr_.opeer = soa.Decode<mirror::Object>(thread_peer).Ptr();
}
self->GetJniEnv()->SetLongField(thread_peer,
WellKnownClasses::java_lang_Thread_nativePeer,
reinterpret_cast<jlong>(self));
return true;
};
return Attach(thread_name, as_daemon, set_peer_action);
}
void Thread::CreatePeer(const char* name, bool as_daemon, jobject thread_group) {
Runtime* runtime = Runtime::Current();
CHECK(runtime->IsStarted());
JNIEnv* env = tlsPtr_.jni_env;
if (thread_group == nullptr) {
thread_group = runtime->GetMainThreadGroup();
}
ScopedLocalRef<jobject> thread_name(env, env->NewStringUTF(name));
// Add missing null check in case of OOM b/18297817
if (name != nullptr && thread_name.get() == nullptr) {
CHECK(IsExceptionPending());
return;
}
jint thread_priority = GetNativePriority();
jboolean thread_is_daemon = as_daemon;
ScopedLocalRef<jobject> peer(env, env->AllocObject(WellKnownClasses::java_lang_Thread));
if (peer.get() == nullptr) {
CHECK(IsExceptionPending());
return;
}
{
ScopedObjectAccess soa(this);
tlsPtr_.opeer = soa.Decode<mirror::Object>(peer.get()).Ptr();
}
env->CallNonvirtualVoidMethod(peer.get(),
WellKnownClasses::java_lang_Thread,
WellKnownClasses::java_lang_Thread_init,
thread_group, thread_name.get(), thread_priority, thread_is_daemon);
if (IsExceptionPending()) {
return;
}
Thread* self = this;
DCHECK_EQ(self, Thread::Current());
env->SetLongField(peer.get(), WellKnownClasses::java_lang_Thread_nativePeer,
reinterpret_cast<jlong>(self));
ScopedObjectAccess soa(self);
StackHandleScope<1> hs(self);
MutableHandle<mirror::String> peer_thread_name(hs.NewHandle(GetThreadName()));
if (peer_thread_name.Get() == nullptr) {
// The Thread constructor should have set the Thread.name to a
// non-null value. However, because we can run without code
// available (in the compiler, in tests), we manually assign the
// fields the constructor should have set.
if (runtime->IsActiveTransaction()) {
InitPeer<true>(soa, thread_is_daemon, thread_group, thread_name.get(), thread_priority);
} else {
InitPeer<false>(soa, thread_is_daemon, thread_group, thread_name.get(), thread_priority);
}
peer_thread_name.Assign(GetThreadName());
}
// 'thread_name' may have been null, so don't trust 'peer_thread_name' to be non-null.
if (peer_thread_name.Get() != nullptr) {
SetThreadName(peer_thread_name->ToModifiedUtf8().c_str());
}
}
template<bool kTransactionActive>
void Thread::InitPeer(ScopedObjectAccess& soa, jboolean thread_is_daemon, jobject thread_group,
jobject thread_name, jint thread_priority) {
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_daemon)->
SetBoolean<kTransactionActive>(tlsPtr_.opeer, thread_is_daemon);
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_group)->
SetObject<kTransactionActive>(tlsPtr_.opeer, soa.Decode<mirror::Object>(thread_group));
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_name)->
SetObject<kTransactionActive>(tlsPtr_.opeer, soa.Decode<mirror::Object>(thread_name));
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_priority)->
SetInt<kTransactionActive>(tlsPtr_.opeer, thread_priority);
}
void Thread::SetThreadName(const char* name) {
tlsPtr_.name->assign(name);
::art::SetThreadName(name);
Dbg::DdmSendThreadNotification(this, CHUNK_TYPE("THNM"));
}
static void GetThreadStack(pthread_t thread,
void** stack_base,
size_t* stack_size,
size_t* guard_size) {
#if defined(__APPLE__)
*stack_size = pthread_get_stacksize_np(thread);
void* stack_addr = pthread_get_stackaddr_np(thread);
// Check whether stack_addr is the base or end of the stack.
// (On Mac OS 10.7, it's the end.)
int stack_variable;
if (stack_addr > &stack_variable) {
*stack_base = reinterpret_cast<uint8_t*>(stack_addr) - *stack_size;
} else {
*stack_base = stack_addr;
}
// This is wrong, but there doesn't seem to be a way to get the actual value on the Mac.
pthread_attr_t attributes;
CHECK_PTHREAD_CALL(pthread_attr_init, (&attributes), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_getguardsize, (&attributes, guard_size), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_destroy, (&attributes), __FUNCTION__);
#else
pthread_attr_t attributes;
CHECK_PTHREAD_CALL(pthread_getattr_np, (thread, &attributes), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_getstack, (&attributes, stack_base, stack_size), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_getguardsize, (&attributes, guard_size), __FUNCTION__);
CHECK_PTHREAD_CALL(pthread_attr_destroy, (&attributes), __FUNCTION__);
#if defined(__GLIBC__)
// If we're the main thread, check whether we were run with an unlimited stack. In that case,
// glibc will have reported a 2GB stack for our 32-bit process, and our stack overflow detection
// will be broken because we'll die long before we get close to 2GB.
bool is_main_thread = (::art::GetTid() == getpid());
if (is_main_thread) {
rlimit stack_limit;
if (getrlimit(RLIMIT_STACK, &stack_limit) == -1) {
PLOG(FATAL) << "getrlimit(RLIMIT_STACK) failed";
}
if (stack_limit.rlim_cur == RLIM_INFINITY) {
size_t old_stack_size = *stack_size;
// Use the kernel default limit as our size, and adjust the base to match.
*stack_size = 8 * MB;
*stack_base = reinterpret_cast<uint8_t*>(*stack_base) + (old_stack_size - *stack_size);
VLOG(threads) << "Limiting unlimited stack (reported as " << PrettySize(old_stack_size) << ")"
<< " to " << PrettySize(*stack_size)
<< " with base " << *stack_base;
}
}
#endif
#endif
}
bool Thread::InitStackHwm() {
void* read_stack_base;
size_t read_stack_size;
size_t read_guard_size;
GetThreadStack(tlsPtr_.pthread_self, &read_stack_base, &read_stack_size, &read_guard_size);
tlsPtr_.stack_begin = reinterpret_cast<uint8_t*>(read_stack_base);
tlsPtr_.stack_size = read_stack_size;
// The minimum stack size we can cope with is the overflow reserved bytes (typically
// 8K) + the protected region size (4K) + another page (4K). Typically this will
// be 8+4+4 = 16K. The thread won't be able to do much with this stack even the GC takes
// between 8K and 12K.
uint32_t min_stack = GetStackOverflowReservedBytes(kRuntimeISA) + kStackOverflowProtectedSize
+ 4 * KB;
if (read_stack_size <= min_stack) {
// Note, as we know the stack is small, avoid operations that could use a lot of stack.
LogHelper::LogLineLowStack(__PRETTY_FUNCTION__,
__LINE__,
::android::base::ERROR,
"Attempt to attach a thread with a too-small stack");
return false;
}
// This is included in the SIGQUIT output, but it's useful here for thread debugging.
VLOG(threads) << StringPrintf("Native stack is at %p (%s with %s guard)",
read_stack_base,
PrettySize(read_stack_size).c_str(),
PrettySize(read_guard_size).c_str());
// Set stack_end_ to the bottom of the stack saving space of stack overflows
Runtime* runtime = Runtime::Current();
bool implicit_stack_check = !runtime->ExplicitStackOverflowChecks() && !runtime->IsAotCompiler();
// Valgrind on arm doesn't give the right values here. Do not install the guard page, and
// effectively disable stack overflow checks (we'll get segfaults, potentially) by setting
// stack_begin to 0.
const bool valgrind_on_arm =
(kRuntimeISA == kArm || kRuntimeISA == kArm64) &&
kMemoryToolIsValgrind &&
RUNNING_ON_MEMORY_TOOL != 0;
if (valgrind_on_arm) {
tlsPtr_.stack_begin = nullptr;
}
ResetDefaultStackEnd();
// Install the protected region if we are doing implicit overflow checks.
if (implicit_stack_check && !valgrind_on_arm) {
// The thread might have protected region at the bottom. We need
// to install our own region so we need to move the limits
// of the stack to make room for it.
tlsPtr_.stack_begin += read_guard_size + kStackOverflowProtectedSize;
tlsPtr_.stack_end += read_guard_size + kStackOverflowProtectedSize;
tlsPtr_.stack_size -= read_guard_size;
InstallImplicitProtection();
}
// Sanity check.
CHECK_GT(FindStackTop(), reinterpret_cast<void*>(tlsPtr_.stack_end));
return true;
}
void Thread::ShortDump(std::ostream& os) const {
os << "Thread[";
if (GetThreadId() != 0) {
// If we're in kStarting, we won't have a thin lock id or tid yet.
os << GetThreadId()
<< ",tid=" << GetTid() << ',';
}
os << GetState()
<< ",Thread*=" << this
<< ",peer=" << tlsPtr_.opeer
<< ",\"" << (tlsPtr_.name != nullptr ? *tlsPtr_.name : "null") << "\""
<< "]";
}
void Thread::Dump(std::ostream& os, bool dump_native_stack, BacktraceMap* backtrace_map) const {
DumpState(os);
DumpStack(os, dump_native_stack, backtrace_map);
}
mirror::String* Thread::GetThreadName() const {
ArtField* f = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_name);
if (tlsPtr_.opeer == nullptr) {
return nullptr;
}
ObjPtr<mirror::Object> name = f->GetObject(tlsPtr_.opeer);
return name == nullptr ? nullptr : name->AsString();
}
void Thread::GetThreadName(std::string& name) const {
name.assign(*tlsPtr_.name);
}
uint64_t Thread::GetCpuMicroTime() const {
#if defined(__linux__)
clockid_t cpu_clock_id;
pthread_getcpuclockid(tlsPtr_.pthread_self, &cpu_clock_id);
timespec now;
clock_gettime(cpu_clock_id, &now);
return static_cast<uint64_t>(now.tv_sec) * UINT64_C(1000000) + now.tv_nsec / UINT64_C(1000);
#else // __APPLE__
UNIMPLEMENTED(WARNING);
return -1;
#endif
}
// Attempt to rectify locks so that we dump thread list with required locks before exiting.
static void UnsafeLogFatalForSuspendCount(Thread* self, Thread* thread) NO_THREAD_SAFETY_ANALYSIS {
LOG(ERROR) << *thread << " suspend count already zero.";
Locks::thread_suspend_count_lock_->Unlock(self);
if (!Locks::mutator_lock_->IsSharedHeld(self)) {
Locks::mutator_lock_->SharedTryLock(self);
if (!Locks::mutator_lock_->IsSharedHeld(self)) {
LOG(WARNING) << "Dumping thread list without holding mutator_lock_";
}
}
if (!Locks::thread_list_lock_->IsExclusiveHeld(self)) {
Locks::thread_list_lock_->TryLock(self);
if (!Locks::thread_list_lock_->IsExclusiveHeld(self)) {
LOG(WARNING) << "Dumping thread list without holding thread_list_lock_";
}
}
std::ostringstream ss;
Runtime::Current()->GetThreadList()->Dump(ss);
LOG(FATAL) << ss.str();
}
bool Thread::ModifySuspendCountInternal(Thread* self,
int delta,
AtomicInteger* suspend_barrier,
bool for_debugger) {
if (kIsDebugBuild) {
DCHECK(delta == -1 || delta == +1 || delta == -tls32_.debug_suspend_count)
<< delta << " " << tls32_.debug_suspend_count << " " << this;
DCHECK_GE(tls32_.suspend_count, tls32_.debug_suspend_count) << this;
Locks::thread_suspend_count_lock_->AssertHeld(self);
if (this != self && !IsSuspended()) {
Locks::thread_list_lock_->AssertHeld(self);
}
}
if (UNLIKELY(delta < 0 && tls32_.suspend_count <= 0)) {
UnsafeLogFatalForSuspendCount(self, this);
return false;
}
if (kUseReadBarrier && delta > 0 && this != self && tlsPtr_.flip_function != nullptr) {
// Force retry of a suspend request if it's in the middle of a thread flip to avoid a
// deadlock. b/31683379.
return false;
}
uint16_t flags = kSuspendRequest;
if (delta > 0 && suspend_barrier != nullptr) {
uint32_t available_barrier = kMaxSuspendBarriers;
for (uint32_t i = 0; i < kMaxSuspendBarriers; ++i) {
if (tlsPtr_.active_suspend_barriers[i] == nullptr) {
available_barrier = i;
break;
}
}
if (available_barrier == kMaxSuspendBarriers) {
// No barrier spaces available, we can't add another.
return false;
}
tlsPtr_.active_suspend_barriers[available_barrier] = suspend_barrier;
flags |= kActiveSuspendBarrier;
}
tls32_.suspend_count += delta;
if (for_debugger) {
tls32_.debug_suspend_count += delta;
}
if (tls32_.suspend_count == 0) {
AtomicClearFlag(kSuspendRequest);
} else {
// Two bits might be set simultaneously.
tls32_.state_and_flags.as_atomic_int.FetchAndOrSequentiallyConsistent(flags);
TriggerSuspend();
}
return true;
}
bool Thread::PassActiveSuspendBarriers(Thread* self) {
// Grab the suspend_count lock and copy the current set of
// barriers. Then clear the list and the flag. The ModifySuspendCount
// function requires the lock so we prevent a race between setting
// the kActiveSuspendBarrier flag and clearing it.
AtomicInteger* pass_barriers[kMaxSuspendBarriers];
{
MutexLock mu(self, *Locks::thread_suspend_count_lock_);
if (!ReadFlag(kActiveSuspendBarrier)) {
// quick exit test: the barriers have already been claimed - this is
// possible as there may be a race to claim and it doesn't matter
// who wins.
// All of the callers of this function (except the SuspendAllInternal)
// will first test the kActiveSuspendBarrier flag without lock. Here
// double-check whether the barrier has been passed with the
// suspend_count lock.
return false;
}
for (uint32_t i = 0; i < kMaxSuspendBarriers; ++i) {
pass_barriers[i] = tlsPtr_.active_suspend_barriers[i];
tlsPtr_.active_suspend_barriers[i] = nullptr;
}
AtomicClearFlag(kActiveSuspendBarrier);
}
uint32_t barrier_count = 0;
for (uint32_t i = 0; i < kMaxSuspendBarriers; i++) {
AtomicInteger* pending_threads = pass_barriers[i];
if (pending_threads != nullptr) {
bool done = false;
do {
int32_t cur_val = pending_threads->LoadRelaxed();
CHECK_GT(cur_val, 0) << "Unexpected value for PassActiveSuspendBarriers(): " << cur_val;
// Reduce value by 1.
done = pending_threads->CompareExchangeWeakRelaxed(cur_val, cur_val - 1);
#if ART_USE_FUTEXES
if (done && (cur_val - 1) == 0) { // Weak CAS may fail spuriously.
futex(pending_threads->Address(), FUTEX_WAKE, -1, nullptr, nullptr, 0);
}
#endif
} while (!done);
++barrier_count;
}
}
CHECK_GT(barrier_count, 0U);
return true;
}
void Thread::ClearSuspendBarrier(AtomicInteger* target) {
CHECK(ReadFlag(kActiveSuspendBarrier));
bool clear_flag = true;
for (uint32_t i = 0; i < kMaxSuspendBarriers; ++i) {
AtomicInteger* ptr = tlsPtr_.active_suspend_barriers[i];
if (ptr == target) {
tlsPtr_.active_suspend_barriers[i] = nullptr;
} else if (ptr != nullptr) {
clear_flag = false;
}
}
if (LIKELY(clear_flag)) {
AtomicClearFlag(kActiveSuspendBarrier);
}
}
void Thread::RunCheckpointFunction() {
bool done = false;
do {
// Grab the suspend_count lock and copy the checkpoints one by one. When the last checkpoint is
// copied, clear the list and the flag. The RequestCheckpoint function will also grab this lock
// to prevent a race between setting the kCheckpointRequest flag and clearing it.
Closure* checkpoint = nullptr;
{
MutexLock mu(this, *Locks::thread_suspend_count_lock_);
if (tlsPtr_.checkpoint_function != nullptr) {
checkpoint = tlsPtr_.checkpoint_function;
if (!checkpoint_overflow_.empty()) {
// Overflow list not empty, copy the first one out and continue.
tlsPtr_.checkpoint_function = checkpoint_overflow_.front();
checkpoint_overflow_.pop_front();
} else {
// No overflow checkpoints, this means that we are on the last pending checkpoint.
tlsPtr_.checkpoint_function = nullptr;
AtomicClearFlag(kCheckpointRequest);
done = true;
}
} else {
LOG(FATAL) << "Checkpoint flag set without pending checkpoint";
}
}
// Outside the lock, run the checkpoint functions that we collected.
ScopedTrace trace("Run checkpoint function");
DCHECK(checkpoint != nullptr);
checkpoint->Run(this);
} while (!done);
}
void Thread::RunEmptyCheckpoint() {
DCHECK_EQ(Thread::Current(), this);
AtomicClearFlag(kEmptyCheckpointRequest);
Runtime::Current()->GetThreadList()->EmptyCheckpointBarrier()->Pass(this);
}
bool Thread::RequestCheckpoint(Closure* function) {
union StateAndFlags old_state_and_flags;
old_state_and_flags.as_int = tls32_.state_and_flags.as_int;
if (old_state_and_flags.as_struct.state != kRunnable) {
return false; // Fail, thread is suspended and so can't run a checkpoint.
}
// We must be runnable to request a checkpoint.
DCHECK_EQ(old_state_and_flags.as_struct.state, kRunnable);
union StateAndFlags new_state_and_flags;
new_state_and_flags.as_int = old_state_and_flags.as_int;
new_state_and_flags.as_struct.flags |= kCheckpointRequest;
bool success = tls32_.state_and_flags.as_atomic_int.CompareExchangeStrongSequentiallyConsistent(
old_state_and_flags.as_int, new_state_and_flags.as_int);
if (success) {
// Succeeded setting checkpoint flag, now insert the actual checkpoint.
if (tlsPtr_.checkpoint_function == nullptr) {
tlsPtr_.checkpoint_function = function;
} else {
checkpoint_overflow_.push_back(function);
}
CHECK_EQ(ReadFlag(kCheckpointRequest), true);
TriggerSuspend();
}
return success;
}
bool Thread::RequestEmptyCheckpoint() {
union StateAndFlags old_state_and_flags;
old_state_and_flags.as_int = tls32_.state_and_flags.as_int;
if (old_state_and_flags.as_struct.state != kRunnable) {
// If it's not runnable, we don't need to do anything because it won't be in the middle of a
// heap access (eg. the read barrier).
return false;
}
// We must be runnable to request a checkpoint.
DCHECK_EQ(old_state_and_flags.as_struct.state, kRunnable);
union StateAndFlags new_state_and_flags;
new_state_and_flags.as_int = old_state_and_flags.as_int;
new_state_and_flags.as_struct.flags |= kEmptyCheckpointRequest;
bool success = tls32_.state_and_flags.as_atomic_int.CompareExchangeStrongSequentiallyConsistent(
old_state_and_flags.as_int, new_state_and_flags.as_int);
if (success) {
TriggerSuspend();
}
return success;
}
class BarrierClosure : public Closure {
public:
explicit BarrierClosure(Closure* wrapped) : wrapped_(wrapped), barrier_(0) {}
void Run(Thread* self) OVERRIDE {
wrapped_->Run(self);
barrier_.Pass(self);
}
void Wait(Thread* self) {
barrier_.Increment(self, 1);
}
private:
Closure* wrapped_;
Barrier barrier_;
};
void Thread::RequestSynchronousCheckpoint(Closure* function) {
if (this == Thread::Current()) {
// Asked to run on this thread. Just run.
function->Run(this);
return;
}
Thread* self = Thread::Current();
// The current thread is not this thread.
for (;;) {
// If this thread is runnable, try to schedule a checkpoint. Do some gymnastics to not hold the
// suspend-count lock for too long.
if (GetState() == ThreadState::kRunnable) {
BarrierClosure barrier_closure(function);
bool installed = false;
{
MutexLock mu(self, *Locks::thread_suspend_count_lock_);
installed = RequestCheckpoint(&barrier_closure);
}
if (installed) {
barrier_closure.Wait(self);
return;
}
// Fall-through.
}
// This thread is not runnable, make sure we stay suspended, then run the checkpoint.
// Note: ModifySuspendCountInternal also expects the thread_list_lock to be held in
// certain situations.
{
MutexLock mu(self, *Locks::thread_list_lock_);
MutexLock mu2(self, *Locks::thread_suspend_count_lock_);
if (!ModifySuspendCount(self, +1, nullptr, false)) {
// Just retry the loop.
sched_yield();
continue;
}
}
while (GetState() == ThreadState::kRunnable) {
// We became runnable again. Wait till the suspend triggered in ModifySuspendCount
// moves us to suspended.
sched_yield();
}
function->Run(this);
{
MutexLock mu(self, *Locks::thread_list_lock_);
MutexLock mu2(self, *Locks::thread_suspend_count_lock_);
DCHECK_NE(GetState(), ThreadState::kRunnable);
CHECK(ModifySuspendCount(self, -1, nullptr, false));
}
return; // We're done, break out of the loop.
}
}
Closure* Thread::GetFlipFunction() {
Atomic<Closure*>* atomic_func = reinterpret_cast<Atomic<Closure*>*>(&tlsPtr_.flip_function);
Closure* func;
do {
func = atomic_func->LoadRelaxed();
if (func == nullptr) {
return nullptr;
}
} while (!atomic_func->CompareExchangeWeakSequentiallyConsistent(func, nullptr));
DCHECK(func != nullptr);
return func;
}
void Thread::SetFlipFunction(Closure* function) {
CHECK(function != nullptr);
Atomic<Closure*>* atomic_func = reinterpret_cast<Atomic<Closure*>*>(&tlsPtr_.flip_function);
atomic_func->StoreSequentiallyConsistent(function);
}
void Thread::FullSuspendCheck() {
ScopedTrace trace(__FUNCTION__);
VLOG(threads) << this << " self-suspending";
// Make thread appear suspended to other threads, release mutator_lock_.
// Transition to suspended and back to runnable, re-acquire share on mutator_lock_.
ScopedThreadSuspension(this, kSuspended);
VLOG(threads) << this << " self-reviving";
}
static std::string GetSchedulerGroupName(pid_t tid) {
// /proc/<pid>/cgroup looks like this:
// 2:devices:/
// 1:cpuacct,cpu:/
// We want the third field from the line whose second field contains the "cpu" token.
std::string cgroup_file;
if (!ReadFileToString(StringPrintf("/proc/self/task/%d/cgroup", tid), &cgroup_file)) {
return "";
}
std::vector<std::string> cgroup_lines;
Split(cgroup_file, '\n', &cgroup_lines);
for (size_t i = 0; i < cgroup_lines.size(); ++i) {
std::vector<std::string> cgroup_fields;
Split(cgroup_lines[i], ':', &cgroup_fields);
std::vector<std::string> cgroups;
Split(cgroup_fields[1], ',', &cgroups);
for (size_t j = 0; j < cgroups.size(); ++j) {
if (cgroups[j] == "cpu") {
return cgroup_fields[2].substr(1); // Skip the leading slash.
}
}
}
return "";
}
void Thread::DumpState(std::ostream& os, const Thread* thread, pid_t tid) {
std::string group_name;
int priority;
bool is_daemon = false;
Thread* self = Thread::Current();
// If flip_function is not null, it means we have run a checkpoint
// before the thread wakes up to execute the flip function and the
// thread roots haven't been forwarded. So the following access to
// the roots (opeer or methods in the frames) would be bad. Run it
// here. TODO: clean up.
if (thread != nullptr) {
ScopedObjectAccessUnchecked soa(self);
Thread* this_thread = const_cast<Thread*>(thread);
Closure* flip_func = this_thread->GetFlipFunction();
if (flip_func != nullptr) {
flip_func->Run(this_thread);
}
}
// Don't do this if we are aborting since the GC may have all the threads suspended. This will
// cause ScopedObjectAccessUnchecked to deadlock.
if (gAborting == 0 && self != nullptr && thread != nullptr && thread->tlsPtr_.opeer != nullptr) {
ScopedObjectAccessUnchecked soa(self);
priority = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_priority)
->GetInt(thread->tlsPtr_.opeer);
is_daemon = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_daemon)
->GetBoolean(thread->tlsPtr_.opeer);
ObjPtr<mirror::Object> thread_group =
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_group)
->GetObject(thread->tlsPtr_.opeer);
if (thread_group != nullptr) {
ArtField* group_name_field =
jni::DecodeArtField(WellKnownClasses::java_lang_ThreadGroup_name);
ObjPtr<mirror::String> group_name_string =
group_name_field->GetObject(thread_group)->AsString();
group_name = (group_name_string != nullptr) ? group_name_string->ToModifiedUtf8() : "<null>";
}
} else {
priority = GetNativePriority();
}
std::string scheduler_group_name(GetSchedulerGroupName(tid));
if (scheduler_group_name.empty()) {
scheduler_group_name = "default";
}
if (thread != nullptr) {
os << '"' << *thread->tlsPtr_.name << '"';
if (is_daemon) {
os << " daemon";
}
os << " prio=" << priority
<< " tid=" << thread->GetThreadId()
<< " " << thread->GetState();
if (thread->IsStillStarting()) {
os << " (still starting up)";
}
os << "\n";
} else {
os << '"' << ::art::GetThreadName(tid) << '"'
<< " prio=" << priority
<< " (not attached)\n";
}
if (thread != nullptr) {
MutexLock mu(self, *Locks::thread_suspend_count_lock_);
os << " | group=\"" << group_name << "\""
<< " sCount=" << thread->tls32_.suspend_count
<< " dsCount=" << thread->tls32_.debug_suspend_count
<< " flags=" << thread->tls32_.state_and_flags.as_struct.flags
<< " obj=" << reinterpret_cast<void*>(thread->tlsPtr_.opeer)
<< " self=" << reinterpret_cast<const void*>(thread) << "\n";
}
os << " | sysTid=" << tid
<< " nice=" << getpriority(PRIO_PROCESS, tid)
<< " cgrp=" << scheduler_group_name;
if (thread != nullptr) {
int policy;
sched_param sp;
CHECK_PTHREAD_CALL(pthread_getschedparam, (thread->tlsPtr_.pthread_self, &policy, &sp),
__FUNCTION__);
os << " sched=" << policy << "/" << sp.sched_priority
<< " handle=" << reinterpret_cast<void*>(thread->tlsPtr_.pthread_self);
}
os << "\n";
// Grab the scheduler stats for this thread.
std::string scheduler_stats;
if (ReadFileToString(StringPrintf("/proc/self/task/%d/schedstat", tid), &scheduler_stats)) {
scheduler_stats.resize(scheduler_stats.size() - 1); // Lose the trailing '\n'.
} else {
scheduler_stats = "0 0 0";
}
char native_thread_state = '?';
int utime = 0;
int stime = 0;
int task_cpu = 0;
GetTaskStats(tid, &native_thread_state, &utime, &stime, &task_cpu);
os << " | state=" << native_thread_state
<< " schedstat=( " << scheduler_stats << " )"
<< " utm=" << utime
<< " stm=" << stime
<< " core=" << task_cpu
<< " HZ=" << sysconf(_SC_CLK_TCK) << "\n";
if (thread != nullptr) {
os << " | stack=" << reinterpret_cast<void*>(thread->tlsPtr_.stack_begin) << "-"
<< reinterpret_cast<void*>(thread->tlsPtr_.stack_end) << " stackSize="
<< PrettySize(thread->tlsPtr_.stack_size) << "\n";
// Dump the held mutexes.
os << " | held mutexes=";
for (size_t i = 0; i < kLockLevelCount; ++i) {
if (i != kMonitorLock) {
BaseMutex* mutex = thread->GetHeldMutex(static_cast<LockLevel>(i));
if (mutex != nullptr) {
os << " \"" << mutex->GetName() << "\"";
if (mutex->IsReaderWriterMutex()) {
ReaderWriterMutex* rw_mutex = down_cast<ReaderWriterMutex*>(mutex);
if (rw_mutex->GetExclusiveOwnerTid() == static_cast<uint64_t>(tid)) {
os << "(exclusive held)";
} else {
os << "(shared held)";
}
}
}
}
}
os << "\n";
}
}
void Thread::DumpState(std::ostream& os) const {
Thread::DumpState(os, this, GetTid());
}
struct StackDumpVisitor : public StackVisitor {
StackDumpVisitor(std::ostream& os_in, Thread* thread_in, Context* context, bool can_allocate_in)
REQUIRES_SHARED(Locks::mutator_lock_)
: StackVisitor(thread_in, context, StackVisitor::StackWalkKind::kIncludeInlinedFrames),
os(os_in),
can_allocate(can_allocate_in),
last_method(nullptr),
last_line_number(0),
repetition_count(0),
frame_count(0) {}
virtual ~StackDumpVisitor() {
if (frame_count == 0) {
os << " (no managed stack frames)\n";
}
}
bool VisitFrame() REQUIRES_SHARED(Locks::mutator_lock_) {
ArtMethod* m = GetMethod();
if (m->IsRuntimeMethod()) {
return true;
}
m = m->GetInterfaceMethodIfProxy(kRuntimePointerSize);
const int kMaxRepetition = 3;
ObjPtr<mirror::Class> c = m->GetDeclaringClass();
ObjPtr<mirror::DexCache> dex_cache = c->GetDexCache();
int line_number = -1;
if (dex_cache != nullptr) { // be tolerant of bad input
const DexFile* dex_file = dex_cache->GetDexFile();
line_number = annotations::GetLineNumFromPC(dex_file, m, GetDexPc(false));
}
if (line_number == last_line_number && last_method == m) {
++repetition_count;
} else {
if (repetition_count >= kMaxRepetition) {
os << " ... repeated " << (repetition_count - kMaxRepetition) << " times\n";
}
repetition_count = 0;
last_line_number = line_number;
last_method = m;
}
if (repetition_count < kMaxRepetition) {
os << " at " << m->PrettyMethod(false);
if (m->IsNative()) {
os << "(Native method)";
} else {
const char* source_file(m->GetDeclaringClassSourceFile());
os << "(" << (source_file != nullptr ? source_file : "unavailable")
<< ":" << line_number << ")";
}
os << "\n";
if (frame_count == 0) {
Monitor::DescribeWait(os, GetThread());
}
if (can_allocate) {
// Visit locks, but do not abort on errors. This would trigger a nested abort.
Monitor::VisitLocks(this, DumpLockedObject, &os, false);
}
}
++frame_count;
return true;
}
static void DumpLockedObject(mirror::Object* o, void* context)
REQUIRES_SHARED(Locks::mutator_lock_) {
std::ostream& os = *reinterpret_cast<std::ostream*>(context);
os << " - locked ";
if (o == nullptr) {
os << "an unknown object";
} else {
if (kUseReadBarrier && Thread::Current()->GetIsGcMarking()) {
// We may call Thread::Dump() in the middle of the CC thread flip and this thread's stack
// may have not been flipped yet and "o" may be a from-space (stale) ref, in which case the
// IdentityHashCode call below will crash. So explicitly mark/forward it here.
o = ReadBarrier::Mark(o);
}
if ((o->GetLockWord(false).GetState() == LockWord::kThinLocked) &&
Locks::mutator_lock_->IsExclusiveHeld(Thread::Current())) {
// Getting the identity hashcode here would result in lock inflation and suspension of the
// current thread, which isn't safe if this is the only runnable thread.
os << StringPrintf("<@addr=0x%" PRIxPTR "> (a %s)", reinterpret_cast<intptr_t>(o),
o->PrettyTypeOf().c_str());
} else {
// IdentityHashCode can cause thread suspension, which would invalidate o if it moved. So
// we get the pretty type beofre we call IdentityHashCode.
const std::string pretty_type(o->PrettyTypeOf());
os << StringPrintf("<0x%08x> (a %s)", o->IdentityHashCode(), pretty_type.c_str());
}
}
os << "\n";
}
std::ostream& os;
const bool can_allocate;
ArtMethod* last_method;
int last_line_number;
int repetition_count;
int frame_count;
};
static bool ShouldShowNativeStack(const Thread* thread)
REQUIRES_SHARED(Locks::mutator_lock_) {
ThreadState state = thread->GetState();
// In native code somewhere in the VM (one of the kWaitingFor* states)? That's interesting.
if (state > kWaiting && state < kStarting) {
return true;
}
// In an Object.wait variant or Thread.sleep? That's not interesting.
if (state == kTimedWaiting || state == kSleeping || state == kWaiting) {
return false;
}
// Threads with no managed stack frames should be shown.
const ManagedStack* managed_stack = thread->GetManagedStack();
if (managed_stack == nullptr || (managed_stack->GetTopQuickFrame() == nullptr &&
managed_stack->GetTopShadowFrame() == nullptr)) {
return true;
}
// In some other native method? That's interesting.
// We don't just check kNative because native methods will be in state kSuspended if they're
// calling back into the VM, or kBlocked if they're blocked on a monitor, or one of the
// thread-startup states if it's early enough in their life cycle (http://b/7432159).
ArtMethod* current_method = thread->GetCurrentMethod(nullptr);
return current_method != nullptr && current_method->IsNative();
}
void Thread::DumpJavaStack(std::ostream& os) const {
// If flip_function is not null, it means we have run a checkpoint
// before the thread wakes up to execute the flip function and the
// thread roots haven't been forwarded. So the following access to
// the roots (locks or methods in the frames) would be bad. Run it
// here. TODO: clean up.
{
Thread* this_thread = const_cast<Thread*>(this);
Closure* flip_func = this_thread->GetFlipFunction();
if (flip_func != nullptr) {
flip_func->Run(this_thread);
}
}
// Dumping the Java stack involves the verifier for locks. The verifier operates under the
// assumption that there is no exception pending on entry. Thus, stash any pending exception.
// Thread::Current() instead of this in case a thread is dumping the stack of another suspended
// thread.
StackHandleScope<1> scope(Thread::Current());
Handle<mirror::Throwable> exc;
bool have_exception = false;
if (IsExceptionPending()) {
exc = scope.NewHandle(GetException());
const_cast<Thread*>(this)->ClearException();
have_exception = true;
}
std::unique_ptr<Context> context(Context::Create());
StackDumpVisitor dumper(os, const_cast<Thread*>(this), context.get(),
!tls32_.throwing_OutOfMemoryError);
dumper.WalkStack();
if (have_exception) {
const_cast<Thread*>(this)->SetException(exc.Get());
}
}
void Thread::DumpStack(std::ostream& os,
bool dump_native_stack,
BacktraceMap* backtrace_map) const {
// TODO: we call this code when dying but may not have suspended the thread ourself. The
// IsSuspended check is therefore racy with the use for dumping (normally we inhibit
// the race with the thread_suspend_count_lock_).
bool dump_for_abort = (gAborting > 0);
bool safe_to_dump = (this == Thread::Current() || IsSuspended());
if (!kIsDebugBuild) {
// We always want to dump the stack for an abort, however, there is no point dumping another
// thread's stack in debug builds where we'll hit the not suspended check in the stack walk.
safe_to_dump = (safe_to_dump || dump_for_abort);
}
if (safe_to_dump) {
// If we're currently in native code, dump that stack before dumping the managed stack.
if (dump_native_stack && (dump_for_abort || ShouldShowNativeStack(this))) {
DumpKernelStack(os, GetTid(), " kernel: ", false);
ArtMethod* method = GetCurrentMethod(nullptr, !dump_for_abort);
DumpNativeStack(os, GetTid(), backtrace_map, " native: ", method);
}
DumpJavaStack(os);
} else {
os << "Not able to dump stack of thread that isn't suspended";
}
}
void Thread::ThreadExitCallback(void* arg) {
Thread* self = reinterpret_cast<Thread*>(arg);
if (self->tls32_.thread_exit_check_count == 0) {
LOG(WARNING) << "Native thread exiting without having called DetachCurrentThread (maybe it's "
"going to use a pthread_key_create destructor?): " << *self;
CHECK(is_started_);
#ifdef ART_TARGET_ANDROID
__get_tls()[TLS_SLOT_ART_THREAD_SELF] = self;
#else
CHECK_PTHREAD_CALL(pthread_setspecific, (Thread::pthread_key_self_, self), "reattach self");
#endif
self->tls32_.thread_exit_check_count = 1;
} else {
LOG(FATAL) << "Native thread exited without calling DetachCurrentThread: " << *self;
}
}
void Thread::Startup() {
CHECK(!is_started_);
is_started_ = true;
{
// MutexLock to keep annotalysis happy.
//
// Note we use null for the thread because Thread::Current can
// return garbage since (is_started_ == true) and
// Thread::pthread_key_self_ is not yet initialized.
// This was seen on glibc.
MutexLock mu(nullptr, *Locks::thread_suspend_count_lock_);
resume_cond_ = new ConditionVariable("Thread resumption condition variable",
*Locks::thread_suspend_count_lock_);
}
// Allocate a TLS slot.
CHECK_PTHREAD_CALL(pthread_key_create, (&Thread::pthread_key_self_, Thread::ThreadExitCallback),
"self key");
// Double-check the TLS slot allocation.
if (pthread_getspecific(pthread_key_self_) != nullptr) {
LOG(FATAL) << "Newly-created pthread TLS slot is not nullptr";
}
}
void Thread::FinishStartup() {
Runtime* runtime = Runtime::Current();
CHECK(runtime->IsStarted());
// Finish attaching the main thread.
ScopedObjectAccess soa(Thread::Current());
Thread::Current()->CreatePeer("main", false, runtime->GetMainThreadGroup());
Thread::Current()->AssertNoPendingException();
Runtime::Current()->GetClassLinker()->RunRootClinits();
}
void Thread::Shutdown() {
CHECK(is_started_);
is_started_ = false;
CHECK_PTHREAD_CALL(pthread_key_delete, (Thread::pthread_key_self_), "self key");
MutexLock mu(Thread::Current(), *Locks::thread_suspend_count_lock_);
if (resume_cond_ != nullptr) {
delete resume_cond_;
resume_cond_ = nullptr;
}
}
Thread::Thread(bool daemon)
: tls32_(daemon),
wait_monitor_(nullptr),
interrupted_(false),
can_call_into_java_(true) {
wait_mutex_ = new Mutex("a thread wait mutex");
wait_cond_ = new ConditionVariable("a thread wait condition variable", *wait_mutex_);
tlsPtr_.instrumentation_stack = new std::deque<instrumentation::InstrumentationStackFrame>;
tlsPtr_.name = new std::string(kThreadNameDuringStartup);
tlsPtr_.nested_signal_state = static_cast<jmp_buf*>(malloc(sizeof(jmp_buf)));
static_assert((sizeof(Thread) % 4) == 0U,
"art::Thread has a size which is not a multiple of 4.");
tls32_.state_and_flags.as_struct.flags = 0;
tls32_.state_and_flags.as_struct.state = kNative;
memset(&tlsPtr_.held_mutexes[0], 0, sizeof(tlsPtr_.held_mutexes));
std::fill(tlsPtr_.rosalloc_runs,
tlsPtr_.rosalloc_runs + kNumRosAllocThreadLocalSizeBracketsInThread,
gc::allocator::RosAlloc::GetDedicatedFullRun());
tlsPtr_.checkpoint_function = nullptr;
for (uint32_t i = 0; i < kMaxSuspendBarriers; ++i) {
tlsPtr_.active_suspend_barriers[i] = nullptr;
}
tlsPtr_.flip_function = nullptr;
tlsPtr_.thread_local_mark_stack = nullptr;
tls32_.is_transitioning_to_runnable = false;
}
bool Thread::IsStillStarting() const {
// You might think you can check whether the state is kStarting, but for much of thread startup,
// the thread is in kNative; it might also be in kVmWait.
// You might think you can check whether the peer is null, but the peer is actually created and
// assigned fairly early on, and needs to be.
// It turns out that the last thing to change is the thread name; that's a good proxy for "has
// this thread _ever_ entered kRunnable".
return (tlsPtr_.jpeer == nullptr && tlsPtr_.opeer == nullptr) ||
(*tlsPtr_.name == kThreadNameDuringStartup);
}
void Thread::AssertPendingException() const {
CHECK(IsExceptionPending()) << "Pending exception expected.";
}
void Thread::AssertPendingOOMException() const {
AssertPendingException();
auto* e = GetException();
CHECK_EQ(e->GetClass(), DecodeJObject(WellKnownClasses::java_lang_OutOfMemoryError)->AsClass())
<< e->Dump();
}
void Thread::AssertNoPendingException() const {
if (UNLIKELY(IsExceptionPending())) {
ScopedObjectAccess soa(Thread::Current());
LOG(FATAL) << "No pending exception expected: " << GetException()->Dump();
}
}
void Thread::AssertNoPendingExceptionForNewException(const char* msg) const {
if (UNLIKELY(IsExceptionPending())) {
ScopedObjectAccess soa(Thread::Current());
LOG(FATAL) << "Throwing new exception '" << msg << "' with unexpected pending exception: "
<< GetException()->Dump();
}
}
class MonitorExitVisitor : public SingleRootVisitor {
public:
explicit MonitorExitVisitor(Thread* self) : self_(self) { }
// NO_THREAD_SAFETY_ANALYSIS due to MonitorExit.
void VisitRoot(mirror::Object* entered_monitor, const RootInfo& info ATTRIBUTE_UNUSED)
OVERRIDE NO_THREAD_SAFETY_ANALYSIS {
if (self_->HoldsLock(entered_monitor)) {
LOG(WARNING) << "Calling MonitorExit on object "
<< entered_monitor << " (" << entered_monitor->PrettyTypeOf() << ")"
<< " left locked by native thread "
<< *Thread::Current() << " which is detaching";
entered_monitor->MonitorExit(self_);
}
}
private:
Thread* const self_;
};
void Thread::Destroy() {
Thread* self = this;
DCHECK_EQ(self, Thread::Current());
if (tlsPtr_.jni_env != nullptr) {
{
ScopedObjectAccess soa(self);
MonitorExitVisitor visitor(self);
// On thread detach, all monitors entered with JNI MonitorEnter are automatically exited.
tlsPtr_.jni_env->monitors.VisitRoots(&visitor, RootInfo(kRootVMInternal));
}
// Release locally held global references which releasing may require the mutator lock.
if (tlsPtr_.jpeer != nullptr) {
// If pthread_create fails we don't have a jni env here.
tlsPtr_.jni_env->DeleteGlobalRef(tlsPtr_.jpeer);
tlsPtr_.jpeer = nullptr;
}
if (tlsPtr_.class_loader_override != nullptr) {
tlsPtr_.jni_env->DeleteGlobalRef(tlsPtr_.class_loader_override);
tlsPtr_.class_loader_override = nullptr;
}
}
if (tlsPtr_.opeer != nullptr) {
ScopedObjectAccess soa(self);
// We may need to call user-supplied managed code, do this before final clean-up.
HandleUncaughtExceptions(soa);
RemoveFromThreadGroup(soa);
// this.nativePeer = 0;
if (Runtime::Current()->IsActiveTransaction()) {
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_nativePeer)
->SetLong<true>(tlsPtr_.opeer, 0);
} else {
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_nativePeer)
->SetLong<false>(tlsPtr_.opeer, 0);
}
Runtime* runtime = Runtime::Current();
if (runtime != nullptr) {
runtime->GetRuntimeCallbacks()->ThreadDeath(self);
}
// Thread.join() is implemented as an Object.wait() on the Thread.lock object. Signal anyone
// who is waiting.
ObjPtr<mirror::Object> lock =
jni::DecodeArtField(WellKnownClasses::java_lang_Thread_lock)->GetObject(tlsPtr_.opeer);
// (This conditional is only needed for tests, where Thread.lock won't have been set.)
if (lock != nullptr) {
StackHandleScope<1> hs(self);
Handle<mirror::Object> h_obj(hs.NewHandle(lock));
ObjectLock<mirror::Object> locker(self, h_obj);
locker.NotifyAll();
}
tlsPtr_.opeer = nullptr;
}
{
ScopedObjectAccess soa(self);
Runtime::Current()->GetHeap()->RevokeThreadLocalBuffers(this);
if (kUseReadBarrier) {
Runtime::Current()->GetHeap()->ConcurrentCopyingCollector()->RevokeThreadLocalMarkStack(this);
}
}
}
Thread::~Thread() {
CHECK(tlsPtr_.class_loader_override == nullptr);
CHECK(tlsPtr_.jpeer == nullptr);
CHECK(tlsPtr_.opeer == nullptr);
bool initialized = (tlsPtr_.jni_env != nullptr); // Did Thread::Init run?
if (initialized) {
delete tlsPtr_.jni_env;
tlsPtr_.jni_env = nullptr;
}
CHECK_NE(GetState(), kRunnable);
CHECK(!ReadFlag(kCheckpointRequest));
CHECK(!ReadFlag(kEmptyCheckpointRequest));
CHECK(tlsPtr_.checkpoint_function == nullptr);
CHECK_EQ(checkpoint_overflow_.size(), 0u);
CHECK(tlsPtr_.flip_function == nullptr);
CHECK_EQ(tls32_.is_transitioning_to_runnable, false);
// Make sure we processed all deoptimization requests.
CHECK(tlsPtr_.deoptimization_context_stack == nullptr) << "Missed deoptimization";
CHECK(tlsPtr_.frame_id_to_shadow_frame == nullptr) <<
"Not all deoptimized frames have been consumed by the debugger.";
// We may be deleting a still born thread.
SetStateUnsafe(kTerminated);
delete wait_cond_;
delete wait_mutex_;
if (tlsPtr_.long_jump_context != nullptr) {
delete tlsPtr_.long_jump_context;
}
if (initialized) {
CleanupCpu();
}
if (tlsPtr_.single_step_control != nullptr) {
delete tlsPtr_.single_step_control;
}
delete tlsPtr_.instrumentation_stack;
delete tlsPtr_.name;
delete tlsPtr_.deps_or_stack_trace_sample.stack_trace_sample;
free(tlsPtr_.nested_signal_state);
Runtime::Current()->GetHeap()->AssertThreadLocalBuffersAreRevoked(this);
TearDownAlternateSignalStack();
}
void Thread::HandleUncaughtExceptions(ScopedObjectAccess& soa) {
if (!IsExceptionPending()) {
return;
}
ScopedLocalRef<jobject> peer(tlsPtr_.jni_env, soa.AddLocalReference<jobject>(tlsPtr_.opeer));
ScopedThreadStateChange tsc(this, kNative);
// Get and clear the exception.
ScopedLocalRef<jthrowable> exception(tlsPtr_.jni_env, tlsPtr_.jni_env->ExceptionOccurred());
tlsPtr_.jni_env->ExceptionClear();
// Call the Thread instance's dispatchUncaughtException(Throwable)
tlsPtr_.jni_env->CallVoidMethod(peer.get(),
WellKnownClasses::java_lang_Thread_dispatchUncaughtException,
exception.get());
// If the dispatchUncaughtException threw, clear that exception too.
tlsPtr_.jni_env->ExceptionClear();
}
void Thread::RemoveFromThreadGroup(ScopedObjectAccess& soa) {
// this.group.removeThread(this);
// group can be null if we're in the compiler or a test.
ObjPtr<mirror::Object> ogroup = jni::DecodeArtField(WellKnownClasses::java_lang_Thread_group)
->GetObject(tlsPtr_.opeer);
if (ogroup != nullptr) {
ScopedLocalRef<jobject> group(soa.Env(), soa.AddLocalReference<jobject>(ogroup));
ScopedLocalRef<jobject> peer(soa.Env(), soa.AddLocalReference<jobject>(tlsPtr_.opeer));
ScopedThreadStateChange tsc(soa.Self(), kNative);
tlsPtr_.jni_env->CallVoidMethod(group.get(),
WellKnownClasses::java_lang_ThreadGroup_removeThread,
peer.get());
}
}
bool Thread::HandleScopeContains(jobject obj) const {
StackReference<mirror::Object>* hs_entry =
reinterpret_cast<StackReference<mirror::Object>*>(obj);
for (BaseHandleScope* cur = tlsPtr_.top_handle_scope; cur!= nullptr; cur = cur->GetLink()) {
if (cur->Contains(hs_entry)) {
return true;
}
}
// JNI code invoked from portable code uses shadow frames rather than the handle scope.
return tlsPtr_.managed_stack.ShadowFramesContain(hs_entry);
}
void Thread::HandleScopeVisitRoots(RootVisitor* visitor, uint32_t thread_id) {
BufferedRootVisitor<kDefaultBufferedRootCount> buffered_visitor(
visitor, RootInfo(kRootNativeStack, thread_id));
for (BaseHandleScope* cur = tlsPtr_.top_handle_scope; cur; cur = cur->GetLink()) {
cur->VisitRoots(buffered_visitor);
}
}
ObjPtr<mirror::Object> Thread::DecodeJObject(jobject obj) const {
if (obj == nullptr) {
return nullptr;
}
IndirectRef ref = reinterpret_cast<IndirectRef>(obj);
IndirectRefKind kind = IndirectReferenceTable::GetIndirectRefKind(ref);
ObjPtr<mirror::Object> result;
bool expect_null = false;
// The "kinds" below are sorted by the frequency we expect to encounter them.
if (kind == kLocal) {
IndirectReferenceTable& locals = tlsPtr_.jni_env->locals;
// Local references do not need a read barrier.
result = locals.Get<kWithoutReadBarrier>(ref);
} else if (kind == kHandleScopeOrInvalid) {
// TODO: make stack indirect reference table lookup more efficient.
// Check if this is a local reference in the handle scope.
if (LIKELY(HandleScopeContains(obj))) {
// Read from handle scope.
result = reinterpret_cast<StackReference<mirror::Object>*>(obj)->AsMirrorPtr();
VerifyObject(result);
} else {
tlsPtr_.jni_env->vm->JniAbortF(nullptr, "use of invalid jobject %p", obj);
expect_null = true;
result = nullptr;
}
} else if (kind == kGlobal) {
result = tlsPtr_.jni_env->vm->DecodeGlobal(ref);
} else {
DCHECK_EQ(kind, kWeakGlobal);
result = tlsPtr_.jni_env->vm->DecodeWeakGlobal(const_cast<Thread*>(this), ref);
if (Runtime::Current()->IsClearedJniWeakGlobal(result)) {
// This is a special case where it's okay to return null.
expect_null = true;
result = nullptr;
}
}
if (UNLIKELY(!expect_null && result == nullptr)) {
tlsPtr_.jni_env->vm->JniAbortF(nullptr, "use of deleted %s %p",
ToStr<IndirectRefKind>(kind).c_str(), obj);
}
return result;
}
bool Thread::IsJWeakCleared(jweak obj) const {
CHECK(obj != nullptr);
IndirectRef ref = reinterpret_cast<IndirectRef>(obj);
IndirectRefKind kind = IndirectReferenceTable::GetIndirectRefKind(ref);
CHECK_EQ(kind, kWeakGlobal);
return tlsPtr_.jni_env->vm->IsWeakGlobalCleared(const_cast<Thread*>(this), ref);
}
// Implements java.lang.Thread.interrupted.
bool Thread::Interrupted() {
MutexLock mu(Thread::Current(), *wait_mutex_);
bool interrupted = IsInterruptedLocked();
SetInterruptedLocked(false);
return interrupted;
}
// Implements java.lang.Thread.isInterrupted.
bool Thread::IsInterrupted() {
MutexLock mu(Thread::Current(), *wait_mutex_);
return IsInterruptedLocked();
}
void Thread::Interrupt(Thread* self) {
MutexLock mu(self, *wait_mutex_);
if (interrupted_) {
return;
}
interrupted_ = true;
NotifyLocked(self);
}
void Thread::Notify() {
Thread* self = Thread::Current();
MutexLock mu(self, *wait_mutex_);
NotifyLocked(self);
}
void Thread::NotifyLocked(Thread* self) {
if (wait_monitor_ != nullptr) {
wait_cond_->Signal(self);
}
}
void Thread::SetClassLoaderOverride(jobject class_loader_override) {
if (tlsPtr_.class_loader_override != nullptr) {
GetJniEnv()->DeleteGlobalRef(tlsPtr_.class_loader_override);
}
tlsPtr_.class_loader_override = GetJniEnv()->NewGlobalRef(class_loader_override);
}
class CountStackDepthVisitor : public StackVisitor {
public:
explicit CountStackDepthVisitor(Thread* thread)
REQUIRES_SHARED(Locks::mutator_lock_)
: StackVisitor(thread, nullptr, StackVisitor::StackWalkKind::kIncludeInlinedFrames),
depth_(0), skip_depth_(0), skipping_(true) {}
bool VisitFrame() REQUIRES_SHARED(Locks::mutator_lock_) {
// We want to skip frames up to and including the exception's constructor.
// Note we also skip the frame if it doesn't have a method (namely the callee
// save frame)
ArtMethod* m = GetMethod();
if (skipping_ && !m->IsRuntimeMethod() &&
!mirror::Throwable::GetJavaLangThrowable()->IsAssignableFrom(m->GetDeclaringClass())) {
skipping_ = false;
}
if (!skipping_) {
if (!m->IsRuntimeMethod()) { // Ignore runtime frames (in particular callee save).
++depth_;
}
} else {
++skip_depth_;
}
return true;
}
int GetDepth() const {
return depth_;
}
int GetSkipDepth() const {
return skip_depth_;
}
private:
uint32_t depth_;
uint32_t skip_depth_;
bool skipping_;
DISALLOW_COPY_AND_ASSIGN(CountStackDepthVisitor);
};
template<bool kTransactionActive>
class BuildInternalStackTraceVisitor : public StackVisitor {
public:
BuildInternalStackTraceVisitor(Thread* self, Thread* thread, int skip_depth)
: StackVisitor(thread, nullptr, StackVisitor::StackWalkKind::kIncludeInlinedFrames),
self_(self),
skip_depth_(skip_depth),
count_(0),
trace_(nullptr),
pointer_size_(Runtime::Current()->GetClassLinker()->GetImagePointerSize()) {}
bool Init(int depth) REQUIRES_SHARED(Locks::mutator_lock_) ACQUIRE(Roles::uninterruptible_) {
// Allocate method trace as an object array where the first element is a pointer array that
// contains the ArtMethod pointers and dex PCs. The rest of the elements are the declaring
// class of the ArtMethod pointers.
ClassLinker* class_linker = Runtime::Current()->GetClassLinker();
StackHandleScope<1> hs(self_);
ObjPtr<mirror::Class> array_class = class_linker->GetClassRoot(ClassLinker::kObjectArrayClass);
// The first element is the methods and dex pc array, the other elements are declaring classes
// for the methods to ensure classes in the stack trace don't get unloaded.
Handle<mirror::ObjectArray<mirror::Object>> trace(
hs.NewHandle(
mirror::ObjectArray<mirror::Object>::Alloc(hs.Self(), array_class, depth + 1)));
if (trace.Get() == nullptr) {
// Acquire uninterruptible_ in all paths.
self_->StartAssertNoThreadSuspension("Building internal stack trace");
self_->AssertPendingOOMException();
return false;
}
ObjPtr<mirror::PointerArray> methods_and_pcs =
class_linker->AllocPointerArray(self_, depth * 2);
const char* last_no_suspend_cause =
self_->StartAssertNoThreadSuspension("Building internal stack trace");
if (methods_and_pcs == nullptr) {
self_->AssertPendingOOMException();
return false;
}
trace->Set(0, methods_and_pcs);
trace_ = trace.Get();
// If We are called from native, use non-transactional mode.
CHECK(last_no_suspend_cause == nullptr) << last_no_suspend_cause;
return true;
}
virtual ~BuildInternalStackTraceVisitor() RELEASE(Roles::uninterruptible_) {
self_->EndAssertNoThreadSuspension(nullptr);
}
bool VisitFrame() REQUIRES_SHARED(Locks::mutator_lock_) {
if (trace_ == nullptr) {
return true; // We're probably trying to fillInStackTrace for an OutOfMemoryError.
}
if (skip_depth_ > 0) {
skip_depth_--;
return true;
}
ArtMethod* m = GetMethod();
if (m->IsRuntimeMethod()) {
return true; // Ignore runtime frames (in particular callee save).
}
ObjPtr<mirror::PointerArray> trace_methods_and_pcs = GetTraceMethodsAndPCs();
trace_methods_and_pcs->SetElementPtrSize<kTransactionActive>(count_, m, pointer_size_);
trace_methods_and_pcs->SetElementPtrSize<kTransactionActive>(
trace_methods_and_pcs->GetLength() / 2 + count_,
m->IsProxyMethod() ? DexFile::kDexNoIndex : GetDexPc(),
pointer_size_);
// Save the declaring class of the method to ensure that the declaring classes of the methods
// do not get unloaded while the stack trace is live.
trace_->Set(count_ + 1, m->GetDeclaringClass());
++count_;
return true;
}
ObjPtr<mirror::PointerArray> GetTraceMethodsAndPCs() const REQUIRES_SHARED(Locks::mutator_lock_) {
return ObjPtr<mirror::PointerArray>::DownCast(MakeObjPtr(trace_->Get(0)));
}
mirror::ObjectArray<mirror::Object>* GetInternalStackTrace() const {
return trace_;
}
private:
Thread* const self_;
// How many more frames to skip.
int32_t skip_depth_;
// Current position down stack trace.
uint32_t count_;
// An object array where the first element is a pointer array that contains the ArtMethod
// pointers on the stack and dex PCs. The rest of the elements are the declaring
// class of the ArtMethod pointers. trace_[i+1] contains the declaring class of the ArtMethod of
// the i'th frame.
mirror::ObjectArray<mirror::Object>* trace_;
// For cross compilation.
const PointerSize pointer_size_;
DISALLOW_COPY_AND_ASSIGN(BuildInternalStackTraceVisitor);
};
template<bool kTransactionActive>
jobject Thread::CreateInternalStackTrace(const ScopedObjectAccessAlreadyRunnable& soa) const {
// Compute depth of stack
CountStackDepthVisitor count_visitor(const_cast<Thread*>(this));
count_visitor.WalkStack();
int32_t depth = count_visitor.GetDepth();
int32_t skip_depth = count_visitor.GetSkipDepth();
// Build internal stack trace.
BuildInternalStackTraceVisitor<kTransactionActive> build_trace_visitor(soa.Self(),
const_cast<Thread*>(this),
skip_depth);
if (!build_trace_visitor.Init(depth)) {
return nullptr; // Allocation failed.
}
build_trace_visitor.WalkStack();
mirror::ObjectArray<mirror::Object>* trace = build_trace_visitor.GetInternalStackTrace();
if (kIsDebugBuild) {
ObjPtr<mirror::PointerArray> trace_methods = build_trace_visitor.GetTraceMethodsAndPCs();
// Second half of trace_methods is dex PCs.
for (uint32_t i = 0; i < static_cast<uint32_t>(trace_methods->GetLength() / 2); ++i) {
auto* method = trace_methods->GetElementPtrSize<ArtMethod*>(
i, Runtime::Current()->GetClassLinker()->GetImagePointerSize());
CHECK(method != nullptr);
}
}
return soa.AddLocalReference<jobject>(trace);
}
template jobject Thread::CreateInternalStackTrace<false>(
const ScopedObjectAccessAlreadyRunnable& soa) const;
template jobject Thread::CreateInternalStackTrace<true>(
const ScopedObjectAccessAlreadyRunnable& soa) const;
bool Thread::IsExceptionThrownByCurrentMethod(ObjPtr<mirror::Throwable> exception) const {
CountStackDepthVisitor count_visitor(const_cast<Thread*>(this));
count_visitor.WalkStack();
return count_visitor.GetDepth() == exception->GetStackDepth();
}
jobjectArray Thread::InternalStackTraceToStackTraceElementArray(
const ScopedObjectAccessAlreadyRunnable& soa,
jobject internal,
jobjectArray output_array,
int* stack_depth) {
// Decode the internal stack trace into the depth, method trace and PC trace.
// Subtract one for the methods and PC trace.
int32_t depth = soa.Decode<mirror::Array>(internal)->GetLength() - 1;
DCHECK_GE(depth, 0);
ClassLinker* const class_linker = Runtime::Current()->GetClassLinker();
jobjectArray result;
if (output_array != nullptr) {
// Reuse the array we were given.
result = output_array;
// ...adjusting the number of frames we'll write to not exceed the array length.
const int32_t traces_length =
soa.Decode<mirror::ObjectArray<mirror::StackTraceElement>>(result)->GetLength();
depth = std::min(depth, traces_length);
} else {
// Create java_trace array and place in local reference table
mirror::ObjectArray<mirror::StackTraceElement>* java_traces =
class_linker->AllocStackTraceElementArray(soa.Self(), depth);
if (java_traces == nullptr) {
return nullptr;
}
result = soa.AddLocalReference<jobjectArray>(java_traces);
}
if (stack_depth != nullptr) {
*stack_depth = depth;
}
for (int32_t i = 0; i < depth; ++i) {
ObjPtr<mirror::ObjectArray<mirror::Object>> decoded_traces =
soa.Decode<mirror::Object>(internal)->AsObjectArray<mirror::Object>();
// Methods and dex PC trace is element 0.
DCHECK(decoded_traces->Get(0)->IsIntArray() || decoded_traces->Get(0)->IsLongArray());
ObjPtr<mirror::PointerArray> const method_trace =
ObjPtr<mirror::PointerArray>::DownCast(MakeObjPtr(decoded_traces->Get(0)));
// Prepare parameters for StackTraceElement(String cls, String method, String file, int line)
ArtMethod* method = method_trace->GetElementPtrSize<ArtMethod*>(i, kRuntimePointerSize);
uint32_t dex_pc = method_trace->GetElementPtrSize<uint32_t>(
i + method_trace->GetLength() / 2, kRuntimePointerSize);
int32_t line_number;
StackHandleScope<3> hs(soa.Self());
auto class_name_object(hs.NewHandle<mirror::String>(nullptr));
auto source_name_object(hs.NewHandle<mirror::String>(nullptr));
if (method->IsProxyMethod()) {
line_number = -1;
class_name_object.Assign(method->GetDeclaringClass()->GetName());
// source_name_object intentionally left null for proxy methods
} else {
line_number = method->GetLineNumFromDexPC(dex_pc);
// Allocate element, potentially triggering GC
// TODO: reuse class_name_object via Class::name_?
const char* descriptor = method->GetDeclaringClassDescriptor();
CHECK(descriptor != nullptr);
std::string class_name(PrettyDescriptor(descriptor));
class_name_object.Assign(
mirror::String::AllocFromModifiedUtf8(soa.Self(), class_name.c_str()));
if (class_name_object.Get() == nullptr) {
soa.Self()->AssertPendingOOMException();
return nullptr;
}
const char* source_file = method->GetDeclaringClassSourceFile();
if (source_file != nullptr) {
source_name_object.Assign(mirror::String::AllocFromModifiedUtf8(soa.Self(), source_file));
if (source_name_object.Get() == nullptr) {
soa.Self()->AssertPendingOOMException();
return nullptr;
}
}
}
const char* method_name = method->GetInterfaceMethodIfProxy(kRuntimePointerSize)->GetName();
CHECK(method_name != nullptr);
Handle<mirror::String> method_name_object(
hs.NewHandle(mirror::String::AllocFromModifiedUtf8(soa.Self(), method_name)));
if (method_name_object.Get() == nullptr) {
return nullptr;
}
ObjPtr<mirror::StackTraceElement> obj =mirror::StackTraceElement::Alloc(soa.Self(),
class_name_object,
method_name_object,
source_name_object,
line_number);
if (obj == nullptr) {
return nullptr;
}
// We are called from native: use non-transactional mode.
soa.Decode<mirror::ObjectArray<mirror::StackTraceElement>>(result)->Set<false>(i, obj);
}
return result;
}
void Thread::ThrowNewExceptionF(const char* exception_class_descriptor, const char* fmt, ...) {
va_list args;
va_start(args, fmt);
ThrowNewExceptionV(exception_class_descriptor, fmt, args);
va_end(args);
}
void Thread::ThrowNewExceptionV(const char* exception_class_descriptor,
const char* fmt, va_list ap) {
std::string msg;
StringAppendV(&msg, fmt, ap);
ThrowNewException(exception_class_descriptor, msg.c_str());
}
void Thread::ThrowNewException(const char* exception_class_descriptor,
const char* msg) {
// Callers should either clear or call ThrowNewWrappedException.
AssertNoPendingExceptionForNewException(msg);
ThrowNewWrappedException(exception_class_descriptor, msg);
}
static ObjPtr<mirror::ClassLoader> GetCurrentClassLoader(Thread* self)
REQUIRES_SHARED(Locks::mutator_lock_) {
ArtMethod* method = self->GetCurrentMethod(nullptr);
return method != nullptr
? method->GetDeclaringClass()->GetClassLoader()
: nullptr;
}
void Thread::ThrowNewWrappedException(const char* exception_class_descriptor,
const char* msg) {
DCHECK_EQ(this, Thread::Current());
ScopedObjectAccessUnchecked soa(this);
StackHandleScope<3> hs(soa.Self());
Handle<mirror::ClassLoader> class_loader(hs.NewHandle(GetCurrentClassLoader(soa.Self())));
ScopedLocalRef<jobject> cause(GetJniEnv(), soa.AddLocalReference<jobject>(GetException()));
ClearException();
Runtime* runtime = Runtime::Current();
auto* cl = runtime->GetClassLinker();
Handle<mirror::Class> exception_class(
hs.NewHandle(cl->FindClass(this, exception_class_descriptor, class_loader)));
if (UNLIKELY(exception_class.Get() == nullptr)) {
CHECK(IsExceptionPending());
LOG(ERROR) << "No exception class " << PrettyDescriptor(exception_class_descriptor);
return;
}
if (UNLIKELY(!runtime->GetClassLinker()->EnsureInitialized(soa.Self(), exception_class, true,
true))) {
DCHECK(IsExceptionPending());
return;
}
DCHECK(!runtime->IsStarted() || exception_class->IsThrowableClass());
Handle<mirror::Throwable> exception(
hs.NewHandle(ObjPtr<mirror::Throwable>::DownCast(exception_class->AllocObject(this))));
// If we couldn't allocate the exception, throw the pre-allocated out of memory exception.
if (exception.Get() == nullptr) {
SetException(Runtime::Current()->GetPreAllocatedOutOfMemoryError());
return;
}
// Choose an appropriate constructor and set up the arguments.
const char* signature;
ScopedLocalRef<jstring> msg_string(GetJniEnv(), nullptr);
if (msg != nullptr) {
// Ensure we remember this and the method over the String allocation.
msg_string.reset(
soa.AddLocalReference<jstring>(mirror::String::AllocFromModifiedUtf8(this, msg)));
if (UNLIKELY(msg_string.get() == nullptr)) {
CHECK(IsExceptionPending()); // OOME.
return;
}
if (cause.get() == nullptr) {
signature = "(Ljava/lang/String;)V";
} else {
signature = "(Ljava/lang/String;Ljava/lang/Throwable;)V";
}
} else {
if (cause.get() == nullptr) {
signature = "()V";
} else {
signature = "(Ljava/lang/Throwable;)V";
}
}
ArtMethod* exception_init_method =
exception_class->FindDeclaredDirectMethod("<init>", signature, cl->GetImagePointerSize());
CHECK(exception_init_method != nullptr) << "No <init>" << signature << " in "
<< PrettyDescriptor(exception_class_descriptor);
if (UNLIKELY(!runtime->IsStarted())) {
// Something is trying to throw an exception without a started runtime, which is the common
// case in the compiler. We won't be able to invoke the constructor of the exception, so set
// the exception fields directly.
if (msg != nullptr) {
exception->SetDetailMessage(DecodeJObject(msg_string.get())->AsString());
}
if (cause.get() != nullptr) {
exception->SetCause(DecodeJObject(cause.get())->AsThrowable());
}
ScopedLocalRef<jobject> trace(GetJniEnv(),
Runtime::Current()->IsActiveTransaction()
? CreateInternalStackTrace<true>(soa)
: CreateInternalStackTrace<false>(soa));
if (trace.get() != nullptr) {
exception->SetStackState(DecodeJObject(trace.get()).Ptr());
}
SetException(exception.Get());
} else {
jvalue jv_args[2];
size_t i = 0;
if (msg != nullptr) {
jv_args[i].l = msg_string.get();
++i;
}
if (cause.get() != nullptr) {
jv_args[i].l = cause.get();
++i;
}
ScopedLocalRef<jobject> ref(soa.Env(), soa.AddLocalReference<jobject>(exception.Get()));
InvokeWithJValues(soa, ref.get(), jni::EncodeArtMethod(exception_init_method), jv_args);
if (LIKELY(!IsExceptionPending())) {
SetException(exception.Get());
}
}
}
void Thread::ThrowOutOfMemoryError(const char* msg) {
LOG(WARNING) << StringPrintf("Throwing OutOfMemoryError \"%s\"%s",
msg, (tls32_.throwing_OutOfMemoryError ? " (recursive case)" : ""));
if (!tls32_.throwing_OutOfMemoryError) {
tls32_.throwing_OutOfMemoryError = true;
ThrowNewException("Ljava/lang/OutOfMemoryError;", msg);
tls32_.throwing_OutOfMemoryError = false;
} else {
Dump(LOG_STREAM(WARNING)); // The pre-allocated OOME has no stack, so help out and log one.
SetException(Runtime::Current()->GetPreAllocatedOutOfMemoryError());
}
}
Thread* Thread::CurrentFromGdb() {
return Thread::Current();
}
void Thread::DumpFromGdb() const {
std::ostringstream ss;
Dump(ss);
std::string str(ss.str());
// log to stderr for debugging command line processes
std::cerr << str;
#ifdef ART_TARGET_ANDROID
// log to logcat for debugging frameworks processes
LOG(INFO) << str;
#endif
}
// Explicitly instantiate 32 and 64bit thread offset dumping support.
template
void Thread::DumpThreadOffset<PointerSize::k32>(std::ostream& os, uint32_t offset);
template
void Thread::DumpThreadOffset<PointerSize::k64>(std::ostream& os, uint32_t offset);
template<PointerSize ptr_size>
void Thread::DumpThreadOffset(std::ostream& os, uint32_t offset) {
#define DO_THREAD_OFFSET(x, y) \
if (offset == (x).Uint32Value()) { \
os << (y); \
return; \
}
DO_THREAD_OFFSET(ThreadFlagsOffset<ptr_size>(), "state_and_flags")
DO_THREAD_OFFSET(CardTableOffset<ptr_size>(), "card_table")
DO_THREAD_OFFSET(ExceptionOffset<ptr_size>(), "exception")
DO_THREAD_OFFSET(PeerOffset<ptr_size>(), "peer");
DO_THREAD_OFFSET(JniEnvOffset<ptr_size>(), "jni_env")
DO_THREAD_OFFSET(SelfOffset<ptr_size>(), "self")
DO_THREAD_OFFSET(StackEndOffset<ptr_size>(), "stack_end")
DO_THREAD_OFFSET(ThinLockIdOffset<ptr_size>(), "thin_lock_thread_id")
DO_THREAD_OFFSET(TopOfManagedStackOffset<ptr_size>(), "top_quick_frame_method")
DO_THREAD_OFFSET(TopShadowFrameOffset<ptr_size>(), "top_shadow_frame")
DO_THREAD_OFFSET(TopHandleScopeOffset<ptr_size>(), "top_handle_scope")
DO_THREAD_OFFSET(ThreadSuspendTriggerOffset<ptr_size>(), "suspend_trigger")
#undef DO_THREAD_OFFSET
#define JNI_ENTRY_POINT_INFO(x) \
if (JNI_ENTRYPOINT_OFFSET(ptr_size, x).Uint32Value() == offset) { \
os << #x; \
return; \
}
JNI_ENTRY_POINT_INFO(pDlsymLookup)
#undef JNI_ENTRY_POINT_INFO
#define QUICK_ENTRY_POINT_INFO(x) \
if (QUICK_ENTRYPOINT_OFFSET(ptr_size, x).Uint32Value() == offset) { \
os << #x; \
return; \
}
QUICK_ENTRY_POINT_INFO(pAllocArrayResolved)
QUICK_ENTRY_POINT_INFO(pAllocArrayResolved8)
QUICK_ENTRY_POINT_INFO(pAllocArrayResolved16)
QUICK_ENTRY_POINT_INFO(pAllocArrayResolved32)
QUICK_ENTRY_POINT_INFO(pAllocArrayResolved64)
QUICK_ENTRY_POINT_INFO(pAllocObjectResolved)
QUICK_ENTRY_POINT_INFO(pAllocObjectInitialized)
QUICK_ENTRY_POINT_INFO(pAllocObjectWithChecks)
QUICK_ENTRY_POINT_INFO(pAllocStringFromBytes)
QUICK_ENTRY_POINT_INFO(pAllocStringFromChars)
QUICK_ENTRY_POINT_INFO(pAllocStringFromString)
QUICK_ENTRY_POINT_INFO(pInstanceofNonTrivial)
QUICK_ENTRY_POINT_INFO(pCheckInstanceOf)
QUICK_ENTRY_POINT_INFO(pInitializeStaticStorage)
QUICK_ENTRY_POINT_INFO(pInitializeTypeAndVerifyAccess)
QUICK_ENTRY_POINT_INFO(pInitializeType)
QUICK_ENTRY_POINT_INFO(pResolveString)
QUICK_ENTRY_POINT_INFO(pSet8Instance)
QUICK_ENTRY_POINT_INFO(pSet8Static)
QUICK_ENTRY_POINT_INFO(pSet16Instance)
QUICK_ENTRY_POINT_INFO(pSet16Static)
QUICK_ENTRY_POINT_INFO(pSet32Instance)
QUICK_ENTRY_POINT_INFO(pSet32Static)
QUICK_ENTRY_POINT_INFO(pSet64Instance)
QUICK_ENTRY_POINT_INFO(pSet64Static)
QUICK_ENTRY_POINT_INFO(pSetObjInstance)
QUICK_ENTRY_POINT_INFO(pSetObjStatic)
QUICK_ENTRY_POINT_INFO(pGetByteInstance)
QUICK_ENTRY_POINT_INFO(pGetBooleanInstance)
QUICK_ENTRY_POINT_INFO(pGetByteStatic)
QUICK_ENTRY_POINT_INFO(pGetBooleanStatic)
QUICK_ENTRY_POINT_INFO(pGetShortInstance)
QUICK_ENTRY_POINT_INFO(pGetCharInstance)
QUICK_ENTRY_POINT_INFO(pGetShortStatic)
QUICK_ENTRY_POINT_INFO(pGetCharStatic)
QUICK_ENTRY_POINT_INFO(pGet32Instance)
QUICK_ENTRY_POINT_INFO(pGet32Static)
QUICK_ENTRY_POINT_INFO(pGet64Instance)
QUICK_ENTRY_POINT_INFO(pGet64Static)
QUICK_ENTRY_POINT_INFO(pGetObjInstance)
QUICK_ENTRY_POINT_INFO(pGetObjStatic)
QUICK_ENTRY_POINT_INFO(pAputObject)
QUICK_ENTRY_POINT_INFO(pJniMethodStart)
QUICK_ENTRY_POINT_INFO(pJniMethodStartSynchronized)
QUICK_ENTRY_POINT_INFO(pJniMethodEnd)
QUICK_ENTRY_POINT_INFO(pJniMethodEndSynchronized)
QUICK_ENTRY_POINT_INFO(pJniMethodEndWithReference)
QUICK_ENTRY_POINT_INFO(pJniMethodEndWithReferenceSynchronized)
QUICK_ENTRY_POINT_INFO(pQuickGenericJniTrampoline)
QUICK_ENTRY_POINT_INFO(pLockObject)
QUICK_ENTRY_POINT_INFO(pUnlockObject)
QUICK_ENTRY_POINT_INFO(pCmpgDouble)
QUICK_ENTRY_POINT_INFO(pCmpgFloat)
QUICK_ENTRY_POINT_INFO(pCmplDouble)
QUICK_ENTRY_POINT_INFO(pCmplFloat)
QUICK_ENTRY_POINT_INFO(pCos)
QUICK_ENTRY_POINT_INFO(pSin)
QUICK_ENTRY_POINT_INFO(pAcos)
QUICK_ENTRY_POINT_INFO(pAsin)
QUICK_ENTRY_POINT_INFO(pAtan)
QUICK_ENTRY_POINT_INFO(pAtan2)
QUICK_ENTRY_POINT_INFO(pCbrt)
QUICK_ENTRY_POINT_INFO(pCosh)
QUICK_ENTRY_POINT_INFO(pExp)
QUICK_ENTRY_POINT_INFO(pExpm1)
QUICK_ENTRY_POINT_INFO(pHypot)
QUICK_ENTRY_POINT_INFO(pLog)
QUICK_ENTRY_POINT_INFO(pLog10)
QUICK_ENTRY_POINT_INFO(pNextAfter)
QUICK_ENTRY_POINT_INFO(pSinh)
QUICK_ENTRY_POINT_INFO(pTan)
QUICK_ENTRY_POINT_INFO(pTanh)
QUICK_ENTRY_POINT_INFO(pFmod)
QUICK_ENTRY_POINT_INFO(pL2d)
QUICK_ENTRY_POINT_INFO(pFmodf)
QUICK_ENTRY_POINT_INFO(pL2f)
QUICK_ENTRY_POINT_INFO(pD2iz)
QUICK_ENTRY_POINT_INFO(pF2iz)
QUICK_ENTRY_POINT_INFO(pIdivmod)
QUICK_ENTRY_POINT_INFO(pD2l)
QUICK_ENTRY_POINT_INFO(pF2l)
QUICK_ENTRY_POINT_INFO(pLdiv)
QUICK_ENTRY_POINT_INFO(pLmod)
QUICK_ENTRY_POINT_INFO(pLmul)
QUICK_ENTRY_POINT_INFO(pShlLong)
QUICK_ENTRY_POINT_INFO(pShrLong)
QUICK_ENTRY_POINT_INFO(pUshrLong)
QUICK_ENTRY_POINT_INFO(pIndexOf)
QUICK_ENTRY_POINT_INFO(pStringCompareTo)
QUICK_ENTRY_POINT_INFO(pMemcpy)
QUICK_ENTRY_POINT_INFO(pQuickImtConflictTrampoline)
QUICK_ENTRY_POINT_INFO(pQuickResolutionTrampoline)
QUICK_ENTRY_POINT_INFO(pQuickToInterpreterBridge)
QUICK_ENTRY_POINT_INFO(pInvokeDirectTrampolineWithAccessCheck)
QUICK_ENTRY_POINT_INFO(pInvokeInterfaceTrampolineWithAccessCheck)
QUICK_ENTRY_POINT_INFO(pInvokeStaticTrampolineWithAccessCheck)
QUICK_ENTRY_POINT_INFO(pInvokeSuperTrampolineWithAccessCheck)
QUICK_ENTRY_POINT_INFO(pInvokeVirtualTrampolineWithAccessCheck)
QUICK_ENTRY_POINT_INFO(pInvokePolymorphic)
QUICK_ENTRY_POINT_INFO(pTestSuspend)
QUICK_ENTRY_POINT_INFO(pDeliverException)
QUICK_ENTRY_POINT_INFO(pThrowArrayBounds)
QUICK_ENTRY_POINT_INFO(pThrowDivZero)
QUICK_ENTRY_POINT_INFO(pThrowNullPointer)
QUICK_ENTRY_POINT_INFO(pThrowStackOverflow)
QUICK_ENTRY_POINT_INFO(pDeoptimize)
QUICK_ENTRY_POINT_INFO(pA64Load)
QUICK_ENTRY_POINT_INFO(pA64Store)
QUICK_ENTRY_POINT_INFO(pNewEmptyString)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_B)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BI)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BII)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BIII)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BIIString)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BString)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BIICharset)
QUICK_ENTRY_POINT_INFO(pNewStringFromBytes_BCharset)
QUICK_ENTRY_POINT_INFO(pNewStringFromChars_C)
QUICK_ENTRY_POINT_INFO(pNewStringFromChars_CII)
QUICK_ENTRY_POINT_INFO(pNewStringFromChars_IIC)
QUICK_ENTRY_POINT_INFO(pNewStringFromCodePoints)
QUICK_ENTRY_POINT_INFO(pNewStringFromString)
QUICK_ENTRY_POINT_INFO(pNewStringFromStringBuffer)
QUICK_ENTRY_POINT_INFO(pNewStringFromStringBuilder)
QUICK_ENTRY_POINT_INFO(pReadBarrierJni)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg00)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg01)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg02)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg03)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg04)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg05)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg06)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg07)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg08)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg09)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg10)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg11)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg12)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg13)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg14)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg15)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg16)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg17)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg18)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg19)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg20)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg21)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg22)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg23)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg24)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg25)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg26)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg27)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg28)
QUICK_ENTRY_POINT_INFO(pReadBarrierMarkReg29)
QUICK_ENTRY_POINT_INFO(pReadBarrierSlow)
QUICK_ENTRY_POINT_INFO(pReadBarrierForRootSlow)
QUICK_ENTRY_POINT_INFO(pJniMethodFastStart)
QUICK_ENTRY_POINT_INFO(pJniMethodFastEnd)
#undef QUICK_ENTRY_POINT_INFO
os << offset;
}
void Thread::QuickDeliverException() {
// Get exception from thread.
ObjPtr<mirror::Throwable> exception = GetException();
CHECK(exception != nullptr);
if (exception == GetDeoptimizationException()) {
artDeoptimize(this);
UNREACHABLE();
}
// This is a real exception: let the instrumentation know about it.
instrumentation::Instrumentation* instrumentation = Runtime::Current()->GetInstrumentation();
if (instrumentation->HasExceptionCaughtListeners() &&
IsExceptionThrownByCurrentMethod(exception)) {
// Instrumentation may cause GC so keep the exception object safe.
StackHandleScope<1> hs(this);
HandleWrapperObjPtr<mirror::Throwable> h_exception(hs.NewHandleWrapper(&exception));
instrumentation->ExceptionCaughtEvent(this, exception.Ptr());
}
// Does instrumentation need to deoptimize the stack?
// Note: we do this *after* reporting the exception to instrumentation in case it
// now requires deoptimization. It may happen if a debugger is attached and requests
// new events (single-step, breakpoint, ...) when the exception is reported.
if (Dbg::IsForcedInterpreterNeededForException(this)) {
NthCallerVisitor visitor(this, 0, false);
visitor.WalkStack();
if (Runtime::Current()->IsAsyncDeoptimizeable(visitor.caller_pc)) {
// Save the exception into the deoptimization context so it can be restored
// before entering the interpreter.
PushDeoptimizationContext(
JValue(), /*is_reference */ false, /* from_code */ false, exception);
artDeoptimize(this);
UNREACHABLE();
} else {
LOG(WARNING) << "Got a deoptimization request on un-deoptimizable method "
<< visitor.caller->PrettyMethod();
}
}
// Don't leave exception visible while we try to find the handler, which may cause class
// resolution.
ClearException();
QuickExceptionHandler exception_handler(this, false);
exception_handler.FindCatch(exception);
exception_handler.UpdateInstrumentationStack();
exception_handler.DoLongJump();
}
Context* Thread::GetLongJumpContext() {
Context* result = tlsPtr_.long_jump_context;
if (result == nullptr) {
result = Context::Create();
} else {
tlsPtr_.long_jump_context = nullptr; // Avoid context being shared.
result->Reset();
}
return result;
}
// Note: this visitor may return with a method set, but dex_pc_ being DexFile:kDexNoIndex. This is
// so we don't abort in a special situation (thinlocked monitor) when dumping the Java stack.
struct CurrentMethodVisitor FINAL : public StackVisitor {
CurrentMethodVisitor(Thread* thread, Context* context, bool abort_on_error)
REQUIRES_SHARED(Locks::mutator_lock_)
: StackVisitor(thread, context, StackVisitor::StackWalkKind::kIncludeInlinedFrames),
this_object_(nullptr),
method_(nullptr),
dex_pc_(0),
abort_on_error_(abort_on_error) {}
bool VisitFrame() OVERRIDE REQUIRES_SHARED(Locks::mutator_lock_) {
ArtMethod* m = GetMethod();
if (m->IsRuntimeMethod()) {
// Continue if this is a runtime method.
return true;
}
if (context_ != nullptr) {
this_object_ = GetThisObject();
}
method_ = m;
dex_pc_ = GetDexPc(abort_on_error_);
return false;
}
ObjPtr<mirror::Object> this_object_;
ArtMethod* method_;
uint32_t dex_pc_;
const bool abort_on_error_;
};
ArtMethod* Thread::GetCurrentMethod(uint32_t* dex_pc, bool abort_on_error) const {
CurrentMethodVisitor visitor(const_cast<Thread*>(this), nullptr, abort_on_error);
visitor.WalkStack(false);
if (dex_pc != nullptr) {
*dex_pc = visitor.dex_pc_;
}
return visitor.method_;
}
bool Thread::HoldsLock(ObjPtr<mirror::Object> object) const {
return object != nullptr && object->GetLockOwnerThreadId() == GetThreadId();
}
// RootVisitor parameters are: (const Object* obj, size_t vreg, const StackVisitor* visitor).
template <typename RootVisitor, bool kPrecise = false>
class ReferenceMapVisitor : public StackVisitor {
public:
ReferenceMapVisitor(Thread* thread, Context* context, RootVisitor& visitor)
REQUIRES_SHARED(Locks::mutator_lock_)
// We are visiting the references in compiled frames, so we do not need
// to know the inlined frames.
: StackVisitor(thread, context, StackVisitor::StackWalkKind::kSkipInlinedFrames),
visitor_(visitor) {}
bool VisitFrame() REQUIRES_SHARED(Locks::mutator_lock_) {
if (false) {
LOG(INFO) << "Visiting stack roots in " << ArtMethod::PrettyMethod(GetMethod())
<< StringPrintf("@ PC:%04x", GetDexPc());
}
ShadowFrame* shadow_frame = GetCurrentShadowFrame();
if (shadow_frame != nullptr) {
VisitShadowFrame(shadow_frame);
} else {
VisitQuickFrame();
}
return true;
}
void VisitShadowFrame(ShadowFrame* shadow_frame) REQUIRES_SHARED(Locks::mutator_lock_) {
ArtMethod* m = shadow_frame->GetMethod();
VisitDeclaringClass(m);
DCHECK(m != nullptr);
size_t num_regs = shadow_frame->NumberOfVRegs();
DCHECK(m->IsNative() || shadow_frame->HasReferenceArray());
// handle scope for JNI or References for interpreter.
for (size_t reg = 0; reg < num_regs; ++reg) {
mirror::Object* ref = shadow_frame->GetVRegReference(reg);
if (ref != nullptr) {
mirror::Object* new_ref = ref;
visitor_(&new_ref, reg, this);
if (new_ref != ref) {
shadow_frame->SetVRegReference(reg, new_ref);
}
}
}
// Mark lock count map required for structured locking checks.
shadow_frame->GetLockCountData().VisitMonitors(visitor_, -1, this);
}
private:
// Visiting the declaring class is necessary so that we don't unload the class of a method that
// is executing. We need to ensure that the code stays mapped. NO_THREAD_SAFETY_ANALYSIS since
// the threads do not all hold the heap bitmap lock for parallel GC.
void VisitDeclaringClass(ArtMethod* method)
REQUIRES_SHARED(Locks::mutator_lock_)
NO_THREAD_SAFETY_ANALYSIS {
ObjPtr<mirror::Class> klass = method->GetDeclaringClassUnchecked<kWithoutReadBarrier>();
// klass can be null for runtime methods.
if (klass != nullptr) {
if (kVerifyImageObjectsMarked) {
gc::Heap* const heap = Runtime::Current()->GetHeap();
gc::space::ContinuousSpace* space = heap->FindContinuousSpaceFromObject(klass,
/*fail_ok*/true);
if (space != nullptr && space->IsImageSpace()) {
bool failed = false;
if (!space->GetLiveBitmap()->Test(klass.Ptr())) {
failed = true;
LOG(FATAL_WITHOUT_ABORT) << "Unmarked object in image " << *space;
} else if (!heap->GetLiveBitmap()->Test(klass.Ptr())) {
failed = true;
LOG(FATAL_WITHOUT_ABORT) << "Unmarked object in image through live bitmap " << *space;
}
if (failed) {
GetThread()->Dump(LOG_STREAM(FATAL_WITHOUT_ABORT));
space->AsImageSpace()->DumpSections(LOG_STREAM(FATAL_WITHOUT_ABORT));
LOG(FATAL_WITHOUT_ABORT) << "Method@" << method->GetDexMethodIndex() << ":" << method
<< " klass@" << klass.Ptr();
// Pretty info last in case it crashes.
LOG(FATAL) << "Method " << method->PrettyMethod() << " klass "
<< klass->PrettyClass();
}
}
}
mirror::Object* new_ref = klass.Ptr();
visitor_(&new_ref, -1, this);
if (new_ref != klass) {
method->CASDeclaringClass(klass.Ptr(), new_ref->AsClass());
}
}
}
template <typename T>
ALWAYS_INLINE
inline void VisitQuickFrameWithVregCallback() REQUIRES_SHARED(Locks::mutator_lock_) {
ArtMethod** cur_quick_frame = GetCurrentQuickFrame();
DCHECK(cur_quick_frame != nullptr);
ArtMethod* m = *cur_quick_frame;
VisitDeclaringClass(m);
// Process register map (which native and runtime methods don't have)
if (!m->IsNative() && !m->IsRuntimeMethod() && (!m->IsProxyMethod() || m->IsConstructor())) {
const OatQuickMethodHeader* method_header = GetCurrentOatQuickMethodHeader();
DCHECK(method_header->IsOptimized());
auto* vreg_base = reinterpret_cast<StackReference<mirror::Object>*>(
reinterpret_cast<uintptr_t>(cur_quick_frame));
uintptr_t native_pc_offset = method_header->NativeQuickPcOffset(GetCurrentQuickFramePc());
CodeInfo code_info = method_header->GetOptimizedCodeInfo();
CodeInfoEncoding encoding = code_info.ExtractEncoding();
StackMap map = code_info.GetStackMapForNativePcOffset(native_pc_offset, encoding);
DCHECK(map.IsValid());
T vreg_info(m, code_info, encoding, map, visitor_);
// Visit stack entries that hold pointers.
size_t number_of_bits = code_info.GetNumberOfStackMaskBits(encoding);
for (size_t i = 0; i < number_of_bits; ++i) {
if (map.GetStackMaskBit(encoding.stack_map_encoding, i)) {
auto* ref_addr = vreg_base + i;
mirror::Object* ref = ref_addr->AsMirrorPtr();
if (ref != nullptr) {
mirror::Object* new_ref = ref;
vreg_info.VisitStack(&new_ref, i, this);
if (ref != new_ref) {
ref_addr->Assign(new_ref);
}
}
}
}
// Visit callee-save registers that hold pointers.
uint32_t register_mask = map.GetRegisterMask(encoding.stack_map_encoding);
for (size_t i = 0; i < BitSizeOf<uint32_t>(); ++i) {
if (register_mask & (1 << i)) {
mirror::Object** ref_addr = reinterpret_cast<mirror::Object**>(GetGPRAddress(i));
if (kIsDebugBuild && ref_addr == nullptr) {
std::string thread_name;
GetThread()->GetThreadName(thread_name);
LOG(FATAL_WITHOUT_ABORT) << "On thread " << thread_name;
DescribeStack(GetThread());
LOG(FATAL) << "Found an unsaved callee-save register " << i << " (null GPRAddress) "
<< "set in register_mask=" << register_mask << " at " << DescribeLocation();
}
if (*ref_addr != nullptr) {
vreg_info.VisitRegister(ref_addr, i, this);
}
}
}
}
}
void VisitQuickFrame() REQUIRES_SHARED(Locks::mutator_lock_) {
if (kPrecise) {
VisitQuickFramePrecise();
} else {
VisitQuickFrameNonPrecise();
}
}
void VisitQuickFrameNonPrecise() REQUIRES_SHARED(Locks::mutator_lock_) {
struct UndefinedVRegInfo {
UndefinedVRegInfo(ArtMethod* method ATTRIBUTE_UNUSED,
const CodeInfo& code_info ATTRIBUTE_UNUSED,
const CodeInfoEncoding& encoding ATTRIBUTE_UNUSED,
const StackMap& map ATTRIBUTE_UNUSED,
RootVisitor& _visitor)
: visitor(_visitor) {
}
ALWAYS_INLINE
void VisitStack(mirror::Object** ref,
size_t stack_index ATTRIBUTE_UNUSED,
const StackVisitor* stack_visitor)
REQUIRES_SHARED(Locks::mutator_lock_) {
visitor(ref, -1, stack_visitor);
}
ALWAYS_INLINE
void VisitRegister(mirror::Object** ref,
size_t register_index ATTRIBUTE_UNUSED,
const StackVisitor* stack_visitor)
REQUIRES_SHARED(Locks::mutator_lock_) {
visitor(ref, -1, stack_visitor);
}
RootVisitor& visitor;
};
VisitQuickFrameWithVregCallback<UndefinedVRegInfo>();
}
void VisitQuickFramePrecise() REQUIRES_SHARED(Locks::mutator_lock_) {
struct StackMapVRegInfo {
StackMapVRegInfo(ArtMethod* method,
const CodeInfo& _code_info,
const CodeInfoEncoding& _encoding,
const StackMap& map,
RootVisitor& _visitor)
: number_of_dex_registers(method->GetCodeItem()->registers_size_),
code_info(_code_info),
encoding(_encoding),
dex_register_map(code_info.GetDexRegisterMapOf(map,
encoding,
number_of_dex_registers)),
visitor(_visitor) {
}
// TODO: If necessary, we should consider caching a reverse map instead of the linear
// lookups for each location.
void FindWithType(const size_t index,
const DexRegisterLocation::Kind kind,
mirror::Object** ref,
const StackVisitor* stack_visitor)
REQUIRES_SHARED(Locks::mutator_lock_) {
bool found = false;
for (size_t dex_reg = 0; dex_reg != number_of_dex_registers; ++dex_reg) {
DexRegisterLocation location = dex_register_map.GetDexRegisterLocation(
dex_reg, number_of_dex_registers, code_info, encoding);
if (location.GetKind() == kind && static_cast<size_t>(location.GetValue()) == index) {
visitor(ref, dex_reg, stack_visitor);
found = true;
}
}
if (!found) {
// If nothing found, report with -1.
visitor(ref, -1, stack_visitor);
}
}
void VisitStack(mirror::Object** ref, size_t stack_index, const StackVisitor* stack_visitor)
REQUIRES_SHARED(Locks::mutator_lock_) {
const size_t stack_offset = stack_index * kFrameSlotSize;
FindWithType(stack_offset,
DexRegisterLocation::Kind::kInStack,
ref,
stack_visitor);
}
void VisitRegister(mirror::Object** ref,
size_t register_index,
const StackVisitor* stack_visitor)
REQUIRES_SHARED(Locks::mutator_lock_) {
FindWithType(register_index,
DexRegisterLocation::Kind::kInRegister,
ref,
stack_visitor);
}
size_t number_of_dex_registers;
const CodeInfo& code_info;
const CodeInfoEncoding& encoding;
DexRegisterMap dex_register_map;
RootVisitor& visitor;
};
VisitQuickFrameWithVregCallback<StackMapVRegInfo>();
}
// Visitor for when we visit a root.
RootVisitor& visitor_;
};
class RootCallbackVisitor {
public:
RootCallbackVisitor(RootVisitor* visitor, uint32_t tid) : visitor_(visitor), tid_(tid) {}
void operator()(mirror::Object** obj, size_t vreg, const StackVisitor* stack_visitor) const
REQUIRES_SHARED(Locks::mutator_lock_) {
visitor_->VisitRoot(obj, JavaFrameRootInfo(tid_, stack_visitor, vreg));
}
private:
RootVisitor* const visitor_;
const uint32_t tid_;
};
template <bool kPrecise>
void Thread::VisitRoots(RootVisitor* visitor) {
const uint32_t thread_id = GetThreadId();
visitor->VisitRootIfNonNull(&tlsPtr_.opeer, RootInfo(kRootThreadObject, thread_id));
if (tlsPtr_.exception != nullptr && tlsPtr_.exception != GetDeoptimizationException()) {
visitor->VisitRoot(reinterpret_cast<mirror::Object**>(&tlsPtr_.exception),
RootInfo(kRootNativeStack, thread_id));
}
visitor->VisitRootIfNonNull(&tlsPtr_.monitor_enter_object, RootInfo(kRootNativeStack, thread_id));
tlsPtr_.jni_env->locals.VisitRoots(visitor, RootInfo(kRootJNILocal, thread_id));
tlsPtr_.jni_env->monitors.VisitRoots(visitor, RootInfo(kRootJNIMonitor, thread_id));
HandleScopeVisitRoots(visitor, thread_id);
if (tlsPtr_.debug_invoke_req != nullptr) {
tlsPtr_.debug_invoke_req->VisitRoots(visitor, RootInfo(kRootDebugger, thread_id));
}
// Visit roots for deoptimization.
if (tlsPtr_.stacked_shadow_frame_record != nullptr) {
RootCallbackVisitor visitor_to_callback(visitor, thread_id);
ReferenceMapVisitor<RootCallbackVisitor, kPrecise> mapper(this, nullptr, visitor_to_callback);
for (StackedShadowFrameRecord* record = tlsPtr_.stacked_shadow_frame_record;
record != nullptr;
record = record->GetLink()) {
for (ShadowFrame* shadow_frame = record->GetShadowFrame();
shadow_frame != nullptr;
shadow_frame = shadow_frame->GetLink()) {
mapper.VisitShadowFrame(shadow_frame);
}
}
}
for (DeoptimizationContextRecord* record = tlsPtr_.deoptimization_context_stack;
record != nullptr;
record = record->GetLink()) {
if (record->IsReference()) {
visitor->VisitRootIfNonNull(record->GetReturnValueAsGCRoot(),
RootInfo(kRootThreadObject, thread_id));
}
visitor->VisitRootIfNonNull(record->GetPendingExceptionAsGCRoot(),
RootInfo(kRootThreadObject, thread_id));
}
if (tlsPtr_.frame_id_to_shadow_frame != nullptr) {
RootCallbackVisitor visitor_to_callback(visitor, thread_id);
ReferenceMapVisitor<RootCallbackVisitor, kPrecise> mapper(this, nullptr, visitor_to_callback);
for (FrameIdToShadowFrame* record = tlsPtr_.frame_id_to_shadow_frame;
record != nullptr;
record = record->GetNext()) {
mapper.VisitShadowFrame(record->GetShadowFrame());
}
}
for (auto* verifier = tlsPtr_.method_verifier; verifier != nullptr; verifier = verifier->link_) {
verifier->VisitRoots(visitor, RootInfo(kRootNativeStack, thread_id));
}
// Visit roots on this thread's stack
Context* context = GetLongJumpContext();
RootCallbackVisitor visitor_to_callback(visitor, thread_id);
ReferenceMapVisitor<RootCallbackVisitor, kPrecise> mapper(this, context, visitor_to_callback);
mapper.template WalkStack<StackVisitor::CountTransitions::kNo>(false);
ReleaseLongJumpContext(context);
for (instrumentation::InstrumentationStackFrame& frame : *GetInstrumentationStack()) {
visitor->VisitRootIfNonNull(&frame.this_object_, RootInfo(kRootVMInternal, thread_id));
}
}
void Thread::VisitRoots(RootVisitor* visitor, VisitRootFlags flags) {
if ((flags & VisitRootFlags::kVisitRootFlagPrecise) != 0) {
VisitRoots<true>(visitor);
} else {
VisitRoots<false>(visitor);
}
}
class VerifyRootVisitor : public SingleRootVisitor {
public:
void VisitRoot(mirror::Object* root, const RootInfo& info ATTRIBUTE_UNUSED)
OVERRIDE REQUIRES_SHARED(Locks::mutator_lock_) {
VerifyObject(root);
}
};
void Thread::VerifyStackImpl() {
VerifyRootVisitor visitor;
std::unique_ptr<Context> context(Context::Create());
RootCallbackVisitor visitor_to_callback(&visitor, GetThreadId());
ReferenceMapVisitor<RootCallbackVisitor> mapper(this, context.get(), visitor_to_callback);
mapper.WalkStack();
}
// Set the stack end to that to be used during a stack overflow
void Thread::SetStackEndForStackOverflow() {
// During stack overflow we allow use of the full stack.
if (tlsPtr_.stack_end == tlsPtr_.stack_begin) {
// However, we seem to have already extended to use the full stack.
LOG(ERROR) << "Need to increase kStackOverflowReservedBytes (currently "
<< GetStackOverflowReservedBytes(kRuntimeISA) << ")?";
DumpStack(LOG_STREAM(ERROR));
LOG(FATAL) << "Recursive stack overflow.";
}
tlsPtr_.stack_end = tlsPtr_.stack_begin;
// Remove the stack overflow protection if is it set up.
bool implicit_stack_check = !Runtime::Current()->ExplicitStackOverflowChecks();
if (implicit_stack_check) {
if (!UnprotectStack()) {
LOG(ERROR) << "Unable to remove stack protection for stack overflow";
}
}
}
void Thread::SetTlab(uint8_t* start, uint8_t* end) {
DCHECK_LE(start, end);
tlsPtr_.thread_local_start = start;
tlsPtr_.thread_local_pos = tlsPtr_.thread_local_start;
tlsPtr_.thread_local_end = end;
tlsPtr_.thread_local_objects = 0;
}
bool Thread::HasTlab() const {
bool has_tlab = tlsPtr_.thread_local_pos != nullptr;
if (has_tlab) {
DCHECK(tlsPtr_.thread_local_start != nullptr && tlsPtr_.thread_local_end != nullptr);
} else {
DCHECK(tlsPtr_.thread_local_start == nullptr && tlsPtr_.thread_local_end == nullptr);
}
return has_tlab;
}
std::ostream& operator<<(std::ostream& os, const Thread& thread) {
thread.ShortDump(os);
return os;
}
bool Thread::ProtectStack(bool fatal_on_error) {
void* pregion = tlsPtr_.stack_begin - kStackOverflowProtectedSize;
VLOG(threads) << "Protecting stack at " << pregion;
if (mprotect(pregion, kStackOverflowProtectedSize, PROT_NONE) == -1) {
if (fatal_on_error) {
LOG(FATAL) << "Unable to create protected region in stack for implicit overflow check. "
"Reason: "
<< strerror(errno) << " size: " << kStackOverflowProtectedSize;
}
return false;
}
return true;
}
bool Thread::UnprotectStack() {
void* pregion = tlsPtr_.stack_begin - kStackOverflowProtectedSize;
VLOG(threads) << "Unprotecting stack at " << pregion;
return mprotect(pregion, kStackOverflowProtectedSize, PROT_READ|PROT_WRITE) == 0;
}
void Thread::ActivateSingleStepControl(SingleStepControl* ssc) {
CHECK(Dbg::IsDebuggerActive());
CHECK(GetSingleStepControl() == nullptr) << "Single step already active in thread " << *this;
CHECK(ssc != nullptr);
tlsPtr_.single_step_control = ssc;
}
void Thread::DeactivateSingleStepControl() {
CHECK(Dbg::IsDebuggerActive());
CHECK(GetSingleStepControl() != nullptr) << "Single step not active in thread " << *this;
SingleStepControl* ssc = GetSingleStepControl();
tlsPtr_.single_step_control = nullptr;
delete ssc;
}
void Thread::SetDebugInvokeReq(DebugInvokeReq* req) {
CHECK(Dbg::IsDebuggerActive());
CHECK(GetInvokeReq() == nullptr) << "Debug invoke req already active in thread " << *this;
CHECK(Thread::Current() != this) << "Debug invoke can't be dispatched by the thread itself";
CHECK(req != nullptr);
tlsPtr_.debug_invoke_req = req;
}
void Thread::ClearDebugInvokeReq() {
CHECK(GetInvokeReq() != nullptr) << "Debug invoke req not active in thread " << *this;
CHECK(Thread::Current() == this) << "Debug invoke must be finished by the thread itself";
DebugInvokeReq* req = tlsPtr_.debug_invoke_req;
tlsPtr_.debug_invoke_req = nullptr;
delete req;
}
void Thread::PushVerifier(verifier::MethodVerifier* verifier) {
verifier->link_ = tlsPtr_.method_verifier;
tlsPtr_.method_verifier = verifier;
}
void Thread::PopVerifier(verifier::MethodVerifier* verifier) {
CHECK_EQ(tlsPtr_.method_verifier, verifier);
tlsPtr_.method_verifier = verifier->link_;
}
size_t Thread::NumberOfHeldMutexes() const {
size_t count = 0;
for (BaseMutex* mu : tlsPtr_.held_mutexes) {
count += mu != nullptr ? 1 : 0;
}
return count;
}
void Thread::DeoptimizeWithDeoptimizationException(JValue* result) {
DCHECK_EQ(GetException(), Thread::GetDeoptimizationException());
ClearException();
ShadowFrame* shadow_frame =
PopStackedShadowFrame(StackedShadowFrameType::kDeoptimizationShadowFrame);
ObjPtr<mirror::Throwable> pending_exception;
bool from_code = false;
PopDeoptimizationContext(result, &pending_exception, &from_code);
SetTopOfStack(nullptr);
SetTopOfShadowStack(shadow_frame);
// Restore the exception that was pending before deoptimization then interpret the
// deoptimized frames.
if (pending_exception != nullptr) {
SetException(pending_exception);
}
interpreter::EnterInterpreterFromDeoptimize(this, shadow_frame, from_code, result);
}
void Thread::SetException(ObjPtr<mirror::Throwable> new_exception) {
CHECK(new_exception != nullptr);
// TODO: DCHECK(!IsExceptionPending());
tlsPtr_.exception = new_exception.Ptr();
}
bool Thread::IsAotCompiler() {
return Runtime::Current()->IsAotCompiler();
}
} // namespace art