/* Copyright (C) 2017 The Android Open Source Project * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This file implements interfaces from the file jvmti.h. This implementation * is licensed under the same terms as the file jvmti.h. The * copyright and license information for the file jvmti.h follows. * * Copyright (c) 2003, 2011, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ #include #include #include #include "deopt_manager.h" #include "art_jvmti.h" #include "art_method-inl.h" #include "base/enums.h" #include "base/mutex-inl.h" #include "dex/dex_file_annotations.h" #include "dex/modifiers.h" #include "events-inl.h" #include "gc/collector_type.h" #include "gc/heap.h" #include "gc/scoped_gc_critical_section.h" #include "instrumentation.h" #include "jit/jit.h" #include "jni/jni_internal.h" #include "mirror/class-inl.h" #include "mirror/object_array-inl.h" #include "nativehelper/scoped_local_ref.h" #include "read_barrier_config.h" #include "runtime_callbacks.h" #include "scoped_thread_state_change-inl.h" #include "scoped_thread_state_change.h" #include "thread-current-inl.h" #include "thread_list.h" #include "ti_phase.h" namespace openjdkjvmti { // TODO We should make this much more selective in the future so we only return true when we // actually care about the method at this time (ie active frames had locals changed). For now we // just assume that if anything has changed any frame's locals we care about all methods. If nothing // has we only care about methods with active breakpoints on them. In the future we should probably // rewrite all of this to instead do this at the ShadowFrame or thread granularity. bool JvmtiMethodInspectionCallback::IsMethodBeingInspected(art::ArtMethod* method) { // Non-java-debuggable runtimes we need to assume that any method might not be debuggable and // therefore potentially being inspected (due to inlines). If we are debuggable we rely hard on // inlining not being done since we don't keep track of which methods get inlined where and simply // look to see if the method is breakpointed. return !art::Runtime::Current()->IsJavaDebuggable() || manager_->HaveLocalsChanged() || manager_->MethodHasBreakpoints(method); } bool JvmtiMethodInspectionCallback::IsMethodSafeToJit(art::ArtMethod* method) { return !manager_->MethodHasBreakpoints(method); } bool JvmtiMethodInspectionCallback::MethodNeedsDebugVersion( art::ArtMethod* method ATTRIBUTE_UNUSED) { return true; } DeoptManager::DeoptManager() : deoptimization_status_lock_("JVMTI_DeoptimizationStatusLock", static_cast( art::LockLevel::kClassLinkerClassesLock + 1)), deoptimization_condition_("JVMTI_DeoptimizationCondition", deoptimization_status_lock_), performing_deoptimization_(false), global_deopt_count_(0), deopter_count_(0), breakpoint_status_lock_("JVMTI_BreakpointStatusLock", static_cast(art::LockLevel::kAbortLock + 1)), inspection_callback_(this), set_local_variable_called_(false) { } void DeoptManager::Setup() { art::ScopedThreadStateChange stsc(art::Thread::Current(), art::ThreadState::kWaitingForDebuggerToAttach); art::ScopedSuspendAll ssa("Add method Inspection Callback"); art::RuntimeCallbacks* callbacks = art::Runtime::Current()->GetRuntimeCallbacks(); callbacks->AddMethodInspectionCallback(&inspection_callback_); } void DeoptManager::Shutdown() { art::ScopedThreadStateChange stsc(art::Thread::Current(), art::ThreadState::kWaitingForDebuggerToAttach); art::ScopedSuspendAll ssa("remove method Inspection Callback"); art::RuntimeCallbacks* callbacks = art::Runtime::Current()->GetRuntimeCallbacks(); callbacks->RemoveMethodInspectionCallback(&inspection_callback_); } void DeoptManager::DumpDeoptInfo(art::Thread* self, std::ostream& stream) { art::ScopedObjectAccess soa(self); art::MutexLock mutll(self, *art::Locks::thread_list_lock_); art::MutexLock mudsl(self, deoptimization_status_lock_); art::MutexLock mubsl(self, breakpoint_status_lock_); stream << "Deoptimizer count: " << deopter_count_ << "\n"; stream << "Global deopt count: " << global_deopt_count_ << "\n"; stream << "Can perform OSR: " << !set_local_variable_called_.load() << "\n"; for (const auto& [bp, loc] : this->breakpoint_status_) { stream << "Breakpoint: " << bp->PrettyMethod() << " @ 0x" << std::hex << loc << "\n"; } struct DumpThreadDeoptCount : public art::Closure { public: DumpThreadDeoptCount(std::ostream& stream, std::mutex& mu) : cnt_(0), stream_(stream), mu_(mu) {} void Run(art::Thread* self) override { { std::lock_guard lg(mu_); std::string name; self->GetThreadName(name); stream_ << "Thread " << name << " (id: " << std::dec << self->GetThreadId() << ") force interpreter count " << self->ForceInterpreterCount() << "\n"; } // Increment this after unlocking the mutex so we won't race its destructor. cnt_++; } void WaitForCount(size_t threads) { while (cnt_.load() != threads) { sched_yield(); } } private: std::atomic cnt_; std::ostream& stream_; std::mutex& mu_; }; std::mutex mu; DumpThreadDeoptCount dtdc(stream, mu); auto func = [](art::Thread* thread, void* ctx) { reinterpret_cast(ctx)->Run(thread); }; art::Runtime::Current()->GetThreadList()->ForEach(func, &dtdc); } void DeoptManager::FinishSetup() { art::Thread* self = art::Thread::Current(); art::MutexLock mu(self, deoptimization_status_lock_); art::Runtime* runtime = art::Runtime::Current(); // See if we need to do anything. if (!runtime->IsJavaDebuggable()) { // See if we can enable all JVMTI functions. If this is false, only kArtTiVersion agents can be // retrieved and they will all be best-effort. if (PhaseUtil::GetPhaseUnchecked() == JVMTI_PHASE_ONLOAD) { // We are still early enough to change the compiler options and get full JVMTI support. LOG(INFO) << "Openjdkjvmti plugin loaded on a non-debuggable runtime. Changing runtime to " << "debuggable state. Please pass '--debuggable' to dex2oat and " << "'-Xcompiler-option --debuggable' to dalvikvm in the future."; DCHECK(runtime->GetJit() == nullptr) << "Jit should not be running yet!"; runtime->AddCompilerOption("--debuggable"); runtime->SetJavaDebuggable(true); } else { LOG(WARNING) << "Openjdkjvmti plugin was loaded on a non-debuggable Runtime. Plugin was " << "loaded too late to change runtime state to DEBUGGABLE. Only kArtTiVersion " << "(0x" << std::hex << kArtTiVersion << ") environments are available. Some " << "functionality might not work properly."; if (runtime->GetJit() == nullptr && runtime->GetJITOptions()->UseJitCompilation() && !runtime->GetInstrumentation()->IsForcedInterpretOnly()) { // If we don't have a jit we should try to start the jit for performance reasons. We only // need to do this for late attach on non-debuggable processes because for debuggable // processes we already rely on jit and we cannot force this jit to start if we are still in // OnLoad since the runtime hasn't started up sufficiently. This is only expected to happen // on userdebug/eng builds. LOG(INFO) << "Attempting to start jit for openjdkjvmti plugin."; // Note: use rwx allowed = true, because if this is the system server, we will not be // allowed to allocate any JIT code cache, anyways. runtime->CreateJitCodeCache(/*rwx_memory_allowed=*/true); runtime->CreateJit(); if (runtime->GetJit() == nullptr) { LOG(WARNING) << "Could not start jit for openjdkjvmti plugin. This process might be " << "quite slow as it is running entirely in the interpreter. Try running " << "'setenforce 0' and restarting this process."; } } } runtime->DeoptimizeBootImage(); } } bool DeoptManager::MethodHasBreakpoints(art::ArtMethod* method) { art::MutexLock lk(art::Thread::Current(), breakpoint_status_lock_); return MethodHasBreakpointsLocked(method); } bool DeoptManager::MethodHasBreakpointsLocked(art::ArtMethod* method) { auto elem = breakpoint_status_.find(method); return elem != breakpoint_status_.end() && elem->second != 0; } void DeoptManager::RemoveDeoptimizeAllMethods() { art::Thread* self = art::Thread::Current(); art::ScopedThreadSuspension sts(self, art::kSuspended); deoptimization_status_lock_.ExclusiveLock(self); RemoveDeoptimizeAllMethodsLocked(self); } void DeoptManager::AddDeoptimizeAllMethods() { art::Thread* self = art::Thread::Current(); art::ScopedThreadSuspension sts(self, art::kSuspended); deoptimization_status_lock_.ExclusiveLock(self); AddDeoptimizeAllMethodsLocked(self); } void DeoptManager::AddMethodBreakpoint(art::ArtMethod* method) { DCHECK(method->IsInvokable()); DCHECK(!method->IsProxyMethod()) << method->PrettyMethod(); DCHECK(!method->IsNative()) << method->PrettyMethod(); art::Thread* self = art::Thread::Current(); method = method->GetCanonicalMethod(); bool is_default = method->IsDefault(); art::ScopedThreadSuspension sts(self, art::kSuspended); deoptimization_status_lock_.ExclusiveLock(self); { breakpoint_status_lock_.ExclusiveLock(self); DCHECK_GT(deopter_count_, 0u) << "unexpected deotpimization request"; if (MethodHasBreakpointsLocked(method)) { // Don't need to do anything extra. breakpoint_status_[method]++; // Another thread might be deoptimizing the very method we just added new breakpoints for. // Wait for any deopts to finish before moving on. breakpoint_status_lock_.ExclusiveUnlock(self); WaitForDeoptimizationToFinish(self); return; } breakpoint_status_[method] = 1; breakpoint_status_lock_.ExclusiveUnlock(self); } auto instrumentation = art::Runtime::Current()->GetInstrumentation(); if (instrumentation->IsForcedInterpretOnly()) { // We are already interpreting everything so no need to do anything. deoptimization_status_lock_.ExclusiveUnlock(self); return; } else if (is_default) { AddDeoptimizeAllMethodsLocked(self); } else { PerformLimitedDeoptimization(self, method); } } void DeoptManager::RemoveMethodBreakpoint(art::ArtMethod* method) { DCHECK(method->IsInvokable()) << method->PrettyMethod(); DCHECK(!method->IsProxyMethod()) << method->PrettyMethod(); DCHECK(!method->IsNative()) << method->PrettyMethod(); art::Thread* self = art::Thread::Current(); method = method->GetCanonicalMethod(); bool is_default = method->IsDefault(); art::ScopedThreadSuspension sts(self, art::kSuspended); // Ideally we should do a ScopedSuspendAll right here to get the full mutator_lock_ that we might // need but since that is very heavy we will instead just use a condition variable to make sure we // don't race with ourselves. deoptimization_status_lock_.ExclusiveLock(self); bool is_last_breakpoint; { art::MutexLock mu(self, breakpoint_status_lock_); DCHECK_GT(deopter_count_, 0u) << "unexpected deotpimization request"; DCHECK(MethodHasBreakpointsLocked(method)) << "Breakpoint on a method was removed without " << "breakpoints present!"; breakpoint_status_[method] -= 1; is_last_breakpoint = (breakpoint_status_[method] == 0); } auto instrumentation = art::Runtime::Current()->GetInstrumentation(); if (UNLIKELY(instrumentation->IsForcedInterpretOnly())) { // We don't need to do anything since we are interpreting everything anyway. deoptimization_status_lock_.ExclusiveUnlock(self); return; } else if (is_last_breakpoint) { if (UNLIKELY(is_default)) { RemoveDeoptimizeAllMethodsLocked(self); } else { PerformLimitedUndeoptimization(self, method); } } else { // Another thread might be deoptimizing the very methods we just removed breakpoints from. Wait // for any deopts to finish before moving on. WaitForDeoptimizationToFinish(self); } } void DeoptManager::WaitForDeoptimizationToFinishLocked(art::Thread* self) { while (performing_deoptimization_) { deoptimization_condition_.Wait(self); } } void DeoptManager::WaitForDeoptimizationToFinish(art::Thread* self) { WaitForDeoptimizationToFinishLocked(self); deoptimization_status_lock_.ExclusiveUnlock(self); } // Users should make sure that only gc-critical-section safe code is used while a // ScopedDeoptimizationContext exists. class ScopedDeoptimizationContext : public art::ValueObject { public: ScopedDeoptimizationContext(art::Thread* self, DeoptManager* deopt) RELEASE(deopt->deoptimization_status_lock_) ACQUIRE(art::Locks::mutator_lock_) ACQUIRE(art::Roles::uninterruptible_) : self_(self), deopt_(deopt), critical_section_(self_, "JVMTI Deoptimizing methods"), uninterruptible_cause_(nullptr) { deopt_->WaitForDeoptimizationToFinishLocked(self_); DCHECK(!deopt->performing_deoptimization_) << "Already performing deoptimization on another thread!"; // Use performing_deoptimization_ to keep track of the lock. deopt_->performing_deoptimization_ = true; deopt_->deoptimization_status_lock_.Unlock(self_); uninterruptible_cause_ = critical_section_.Enter(art::gc::kGcCauseInstrumentation, art::gc::kCollectorTypeCriticalSection); art::Runtime::Current()->GetThreadList()->SuspendAll("JMVTI Deoptimizing methods", /*long_suspend=*/ false); } ~ScopedDeoptimizationContext() RELEASE(art::Locks::mutator_lock_) RELEASE(art::Roles::uninterruptible_) { // Can be suspended again. critical_section_.Exit(uninterruptible_cause_); // Release the mutator lock. art::Runtime::Current()->GetThreadList()->ResumeAll(); // Let other threads know it's fine to proceed. art::MutexLock lk(self_, deopt_->deoptimization_status_lock_); deopt_->performing_deoptimization_ = false; deopt_->deoptimization_condition_.Broadcast(self_); } private: art::Thread* self_; DeoptManager* deopt_; art::gc::GCCriticalSection critical_section_; const char* uninterruptible_cause_; }; void DeoptManager::AddDeoptimizeAllMethodsLocked(art::Thread* self) { global_deopt_count_++; if (global_deopt_count_ == 1) { PerformGlobalDeoptimization(self); } else { WaitForDeoptimizationToFinish(self); } } void DeoptManager::RemoveDeoptimizeAllMethodsLocked(art::Thread* self) { DCHECK_GT(global_deopt_count_, 0u) << "Request to remove non-existent global deoptimization!"; global_deopt_count_--; if (global_deopt_count_ == 0) { PerformGlobalUndeoptimization(self); } else { WaitForDeoptimizationToFinish(self); } } void DeoptManager::PerformLimitedDeoptimization(art::Thread* self, art::ArtMethod* method) { ScopedDeoptimizationContext sdc(self, this); art::Runtime::Current()->GetInstrumentation()->Deoptimize(method); } void DeoptManager::PerformLimitedUndeoptimization(art::Thread* self, art::ArtMethod* method) { ScopedDeoptimizationContext sdc(self, this); art::Runtime::Current()->GetInstrumentation()->Undeoptimize(method); } void DeoptManager::PerformGlobalDeoptimization(art::Thread* self) { ScopedDeoptimizationContext sdc(self, this); art::Runtime::Current()->GetInstrumentation()->DeoptimizeEverything( kDeoptManagerInstrumentationKey); } void DeoptManager::PerformGlobalUndeoptimization(art::Thread* self) { ScopedDeoptimizationContext sdc(self, this); art::Runtime::Current()->GetInstrumentation()->UndeoptimizeEverything( kDeoptManagerInstrumentationKey); } jvmtiError DeoptManager::AddDeoptimizeThreadMethods(art::ScopedObjectAccessUnchecked& soa, jthread jtarget) { art::Locks::thread_list_lock_->ExclusiveLock(soa.Self()); art::Thread* target = nullptr; jvmtiError err = OK; if (!ThreadUtil::GetNativeThread(jtarget, soa, &target, &err)) { art::Locks::thread_list_lock_->ExclusiveUnlock(soa.Self()); return err; } // We don't need additional locking here because we hold the Thread_list_lock_. if (target->IncrementForceInterpreterCount() == 1) { struct DeoptClosure : public art::Closure { public: explicit DeoptClosure(DeoptManager* man) : man_(man) {} void Run(art::Thread* self) override REQUIRES_SHARED(art::Locks::mutator_lock_) { man_->DeoptimizeThread(self); } private: DeoptManager* man_; }; DeoptClosure c(this); target->RequestSynchronousCheckpoint(&c); } else { art::Locks::thread_list_lock_->ExclusiveUnlock(soa.Self()); } return OK; } jvmtiError DeoptManager::RemoveDeoptimizeThreadMethods(art::ScopedObjectAccessUnchecked& soa, jthread jtarget) { art::MutexLock mu(soa.Self(), *art::Locks::thread_list_lock_); art::Thread* target = nullptr; jvmtiError err = OK; if (!ThreadUtil::GetNativeThread(jtarget, soa, &target, &err)) { return err; } // We don't need additional locking here because we hold the Thread_list_lock_. DCHECK_GT(target->ForceInterpreterCount(), 0u); target->DecrementForceInterpreterCount(); return OK; } void DeoptManager::RemoveDeoptimizationRequester() { art::Thread* self = art::Thread::Current(); art::ScopedThreadStateChange sts(self, art::kSuspended); deoptimization_status_lock_.ExclusiveLock(self); DCHECK_GT(deopter_count_, 0u) << "Removing deoptimization requester without any being present"; deopter_count_--; if (deopter_count_ == 0) { ScopedDeoptimizationContext sdc(self, this); // TODO Give this a real key. art::Runtime::Current()->GetInstrumentation()->DisableDeoptimization(""); return; } else { deoptimization_status_lock_.ExclusiveUnlock(self); } } void DeoptManager::AddDeoptimizationRequester() { art::Thread* self = art::Thread::Current(); art::ScopedThreadStateChange stsc(self, art::kSuspended); deoptimization_status_lock_.ExclusiveLock(self); deopter_count_++; if (deopter_count_ == 1) { ScopedDeoptimizationContext sdc(self, this); art::instrumentation::Instrumentation* instrumentation = art::Runtime::Current()->GetInstrumentation(); // Enable deoptimization instrumentation->EnableDeoptimization(); // Tell instrumentation we will be deopting single threads. instrumentation->EnableSingleThreadDeopt(); } else { deoptimization_status_lock_.ExclusiveUnlock(self); } } void DeoptManager::DeoptimizeThread(art::Thread* target) { // We might or might not be running on the target thread (self) so get Thread::Current // directly. art::gc::ScopedGCCriticalSection sgccs(art::Thread::Current(), art::gc::GcCause::kGcCauseDebugger, art::gc::CollectorType::kCollectorTypeDebugger); art::Runtime::Current()->GetInstrumentation()->InstrumentThreadStack(target); } extern DeoptManager* gDeoptManager; DeoptManager* DeoptManager::Get() { return gDeoptManager; } } // namespace openjdkjvmti