/* * 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 "stack.h" #include "mirror/abstract_method-inl.h" #include "mirror/class-inl.h" #include "mirror/object.h" #include "mirror/object-inl.h" #include "mirror/object_array-inl.h" #include "object_utils.h" #include "thread_list.h" #include "throw_location.h" namespace art { mirror::Object* ShadowFrame::GetThisObject() const { mirror::AbstractMethod* m = GetMethod(); if (m->IsStatic()) { return NULL; } else if (m->IsNative()) { return GetVRegReference(0); } else { const DexFile::CodeItem* code_item = MethodHelper(m).GetCodeItem(); CHECK(code_item != NULL) << PrettyMethod(m); uint16_t reg = code_item->registers_size_ - code_item->ins_size_; return GetVRegReference(reg); } } mirror::Object* ShadowFrame::GetThisObject(uint16_t num_ins) const { mirror::AbstractMethod* m = GetMethod(); if (m->IsStatic()) { return NULL; } else { return GetVRegReference(NumberOfVRegs() - num_ins); } } ThrowLocation ShadowFrame::GetCurrentLocationForThrow() const { return ThrowLocation(GetThisObject(), GetMethod(), GetDexPC()); } size_t ManagedStack::NumJniShadowFrameReferences() const { size_t count = 0; for (const ManagedStack* current_fragment = this; current_fragment != NULL; current_fragment = current_fragment->GetLink()) { for (ShadowFrame* current_frame = current_fragment->top_shadow_frame_; current_frame != NULL; current_frame = current_frame->GetLink()) { if (current_frame->GetMethod()->IsNative()) { // The JNI ShadowFrame only contains references. (For indirect reference.) count += current_frame->NumberOfVRegs(); } } } return count; } bool ManagedStack::ShadowFramesContain(mirror::Object** shadow_frame_entry) const { for (const ManagedStack* current_fragment = this; current_fragment != NULL; current_fragment = current_fragment->GetLink()) { for (ShadowFrame* current_frame = current_fragment->top_shadow_frame_; current_frame != NULL; current_frame = current_frame->GetLink()) { if (current_frame->Contains(shadow_frame_entry)) { return true; } } } return false; } StackVisitor::StackVisitor(Thread* thread, Context* context) : thread_(thread), cur_shadow_frame_(NULL), cur_quick_frame_(NULL), cur_quick_frame_pc_(0), num_frames_(0), cur_depth_(0), context_(context) { DCHECK(thread == Thread::Current() || thread->IsSuspended()) << *thread; } uint32_t StackVisitor::GetDexPc() const { if (cur_shadow_frame_ != NULL) { return cur_shadow_frame_->GetDexPC(); } else if (cur_quick_frame_ != NULL) { return GetMethod()->ToDexPc(cur_quick_frame_pc_); } else { return 0; } } mirror::Object* StackVisitor::GetThisObject() const { mirror::AbstractMethod* m = GetMethod(); if (m->IsStatic()) { return NULL; } else if (m->IsNative()) { if (cur_quick_frame_ != NULL) { StackIndirectReferenceTable* sirt = reinterpret_cast( reinterpret_cast(cur_quick_frame_) + m->GetSirtOffsetInBytes()); return sirt->GetReference(0); } else { return cur_shadow_frame_->GetVRegReference(0); } } else { const DexFile::CodeItem* code_item = MethodHelper(m).GetCodeItem(); if (code_item == NULL) { UNIMPLEMENTED(ERROR) << "Failed to determine this object of abstract or proxy method" << PrettyMethod(m); return NULL; } else { uint16_t reg = code_item->registers_size_ - code_item->ins_size_; return reinterpret_cast(GetVReg(m, reg, kReferenceVReg)); } } } size_t StackVisitor::GetNativePcOffset() const { DCHECK(!IsShadowFrame()); return GetMethod()->NativePcOffset(cur_quick_frame_pc_); } uint32_t StackVisitor::GetVReg(mirror::AbstractMethod* m, uint16_t vreg, VRegKind kind) const { if (cur_quick_frame_ != NULL) { DCHECK(context_ != NULL); // You can't reliably read registers without a context. DCHECK(m == GetMethod()); const VmapTable vmap_table(m->GetVmapTableRaw()); uint32_t vmap_offset; // TODO: IsInContext stops before spotting floating point registers. if (vmap_table.IsInContext(vreg, vmap_offset, kind)) { bool is_float = (kind == kFloatVReg) || (kind == kDoubleLoVReg) || (kind == kDoubleHiVReg); uint32_t spill_mask = is_float ? m->GetFpSpillMask() : m->GetCoreSpillMask(); return GetGPR(vmap_table.ComputeRegister(spill_mask, vmap_offset, kind)); } else { const DexFile::CodeItem* code_item = MethodHelper(m).GetCodeItem(); DCHECK(code_item != NULL) << PrettyMethod(m); // Can't be NULL or how would we compile its instructions? size_t frame_size = m->GetFrameSizeInBytes(); return GetVReg(cur_quick_frame_, code_item, m->GetCoreSpillMask(), m->GetFpSpillMask(), frame_size, vreg); } } else { return cur_shadow_frame_->GetVReg(vreg); } } void StackVisitor::SetVReg(mirror::AbstractMethod* m, uint16_t vreg, uint32_t new_value, VRegKind kind) { if (cur_quick_frame_ != NULL) { DCHECK(context_ != NULL); // You can't reliably write registers without a context. DCHECK(m == GetMethod()); const VmapTable vmap_table(m->GetVmapTableRaw()); uint32_t vmap_offset; // TODO: IsInContext stops before spotting floating point registers. if (vmap_table.IsInContext(vreg, vmap_offset, kind)) { bool is_float = (kind == kFloatVReg) || (kind == kDoubleLoVReg) || (kind == kDoubleHiVReg); uint32_t spill_mask = is_float ? m->GetFpSpillMask() : m->GetCoreSpillMask(); const uint32_t reg = vmap_table.ComputeRegister(spill_mask, vmap_offset, kReferenceVReg); SetGPR(reg, new_value); } else { const DexFile::CodeItem* code_item = MethodHelper(m).GetCodeItem(); DCHECK(code_item != NULL) << PrettyMethod(m); // Can't be NULL or how would we compile its instructions? uint32_t core_spills = m->GetCoreSpillMask(); uint32_t fp_spills = m->GetFpSpillMask(); size_t frame_size = m->GetFrameSizeInBytes(); int offset = GetVRegOffset(code_item, core_spills, fp_spills, frame_size, vreg); byte* vreg_addr = reinterpret_cast(GetCurrentQuickFrame()) + offset; *reinterpret_cast(vreg_addr) = new_value; } } else { return cur_shadow_frame_->SetVReg(vreg, new_value); } } uintptr_t StackVisitor::GetGPR(uint32_t reg) const { DCHECK(cur_quick_frame_ != NULL) << "This is a quick frame routine"; return context_->GetGPR(reg); } void StackVisitor::SetGPR(uint32_t reg, uintptr_t value) { DCHECK(cur_quick_frame_ != NULL) << "This is a quick frame routine"; context_->SetGPR(reg, value); } uintptr_t StackVisitor::GetReturnPc() const { mirror::AbstractMethod** sp = GetCurrentQuickFrame(); DCHECK(sp != NULL); byte* pc_addr = reinterpret_cast(sp) + GetMethod()->GetReturnPcOffsetInBytes(); return *reinterpret_cast(pc_addr); } void StackVisitor::SetReturnPc(uintptr_t new_ret_pc) { mirror::AbstractMethod** sp = GetCurrentQuickFrame(); CHECK(sp != NULL); byte* pc_addr = reinterpret_cast(sp) + GetMethod()->GetReturnPcOffsetInBytes(); *reinterpret_cast(pc_addr) = new_ret_pc; } size_t StackVisitor::ComputeNumFrames(Thread* thread) { struct NumFramesVisitor : public StackVisitor { explicit NumFramesVisitor(Thread* thread) : StackVisitor(thread, NULL), frames(0) {} virtual bool VisitFrame() { frames++; return true; } size_t frames; }; NumFramesVisitor visitor(thread); visitor.WalkStack(true); return visitor.frames; } void StackVisitor::DescribeStack(Thread* thread) { struct DescribeStackVisitor : public StackVisitor { explicit DescribeStackVisitor(Thread* thread) : StackVisitor(thread, NULL) {} virtual bool VisitFrame() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) { LOG(INFO) << "Frame Id=" << GetFrameId() << " " << DescribeLocation(); return true; } }; DescribeStackVisitor visitor(thread); visitor.WalkStack(true); } std::string StackVisitor::DescribeLocation() const { std::string result("Visiting method '"); mirror::AbstractMethod* m = GetMethod(); if (m == NULL) { return "upcall"; } result += PrettyMethod(m); result += StringPrintf("' at dex PC 0x%04zx", GetDexPc()); if (!IsShadowFrame()) { result += StringPrintf(" (native PC %p)", reinterpret_cast(GetCurrentQuickFramePc())); } return result; } instrumentation::InstrumentationStackFrame StackVisitor::GetInstrumentationStackFrame(uint32_t depth) const { return thread_->GetInstrumentationStack()->at(depth); } void StackVisitor::SanityCheckFrame() const { #ifndef NDEBUG mirror::AbstractMethod* method = GetMethod(); CHECK(method->GetClass() == mirror::AbstractMethod::GetMethodClass() || method->GetClass() == mirror::AbstractMethod::GetConstructorClass()); if (cur_quick_frame_ != NULL) { method->AssertPcIsWithinCode(cur_quick_frame_pc_); // Frame sanity. size_t frame_size = method->GetFrameSizeInBytes(); CHECK_NE(frame_size, 0u); // A rough guess at an upper size we expect to see for a frame. The 256 is // a dex register limit. The 16 incorporates callee save spills and // outgoing argument set up. const size_t kMaxExpectedFrameSize = 256 * sizeof(word) + 16; CHECK_LE(frame_size, kMaxExpectedFrameSize); size_t return_pc_offset = method->GetReturnPcOffsetInBytes(); CHECK_LT(return_pc_offset, frame_size); } #endif } void StackVisitor::WalkStack(bool include_transitions) { DCHECK(thread_ == Thread::Current() || thread_->IsSuspended()); CHECK_EQ(cur_depth_, 0U); bool exit_stubs_installed = Runtime::Current()->GetInstrumentation()->AreExitStubsInstalled(); uint32_t instrumentation_stack_depth = 0; for (const ManagedStack* current_fragment = thread_->GetManagedStack(); current_fragment != NULL; current_fragment = current_fragment->GetLink()) { cur_shadow_frame_ = current_fragment->GetTopShadowFrame(); cur_quick_frame_ = current_fragment->GetTopQuickFrame(); cur_quick_frame_pc_ = current_fragment->GetTopQuickFramePc(); if (cur_quick_frame_ != NULL) { // Handle quick stack frames. // Can't be both a shadow and a quick fragment. DCHECK(current_fragment->GetTopShadowFrame() == NULL); mirror::AbstractMethod* method = *cur_quick_frame_; while (method != NULL) { SanityCheckFrame(); bool should_continue = VisitFrame(); if (UNLIKELY(!should_continue)) { return; } if (context_ != NULL) { context_->FillCalleeSaves(*this); } size_t frame_size = method->GetFrameSizeInBytes(); // Compute PC for next stack frame from return PC. size_t return_pc_offset = method->GetReturnPcOffsetInBytes(); byte* return_pc_addr = reinterpret_cast(cur_quick_frame_) + return_pc_offset; uintptr_t return_pc = *reinterpret_cast(return_pc_addr); if (UNLIKELY(exit_stubs_installed)) { // While profiling, the return pc is restored from the side stack, except when walking // the stack for an exception where the side stack will be unwound in VisitFrame. if (GetInstrumentationExitPc() == return_pc) { instrumentation::InstrumentationStackFrame instrumentation_frame = GetInstrumentationStackFrame(instrumentation_stack_depth); instrumentation_stack_depth++; if (GetMethod() == Runtime::Current()->GetCalleeSaveMethod(Runtime::kSaveAll)) { // Skip runtime save all callee frames which are used to deliver exceptions. } else if (instrumentation_frame.interpreter_entry_) { mirror::AbstractMethod* callee = Runtime::Current()->GetCalleeSaveMethod(Runtime::kRefsAndArgs); CHECK_EQ(GetMethod(), callee) << "Expected: " << PrettyMethod(callee) << " Found: " << PrettyMethod(GetMethod()); } else if (instrumentation_frame.method_ != GetMethod()) { LOG(FATAL) << "Expected: " << PrettyMethod(instrumentation_frame.method_) << " Found: " << PrettyMethod(GetMethod()); } if (num_frames_ != 0) { // Check agreement of frame Ids only if num_frames_ is computed to avoid infinite // recursion. CHECK(instrumentation_frame.frame_id_ == GetFrameId()) << "Expected: " << instrumentation_frame.frame_id_ << " Found: " << GetFrameId(); } return_pc = instrumentation_frame.return_pc_; } } cur_quick_frame_pc_ = return_pc; byte* next_frame = reinterpret_cast(cur_quick_frame_) + frame_size; cur_quick_frame_ = reinterpret_cast(next_frame); cur_depth_++; method = *cur_quick_frame_; } } else if (cur_shadow_frame_ != NULL) { do { SanityCheckFrame(); bool should_continue = VisitFrame(); if (UNLIKELY(!should_continue)) { return; } cur_depth_++; cur_shadow_frame_ = cur_shadow_frame_->GetLink(); } while (cur_shadow_frame_ != NULL); } if (include_transitions) { bool should_continue = VisitFrame(); if (!should_continue) { return; } } cur_depth_++; } if (num_frames_ != 0) { CHECK_EQ(cur_depth_, num_frames_); } } } // namespace art