runtime/stack.h - platform/art - Gitiles

 /*
  * 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.
  */

 #ifndef ART_RUNTIME_STACK_H_
 #define ART_RUNTIME_STACK_H_

 #include "dex_file.h"
 #include "instrumentation.h"
 #include "base/macros.h"
 #include "oat/runtime/context.h"

 #include <stdint.h>
 #include <string>

 namespace art {

 namespace mirror {
 class AbstractMethod;
 class Object;
 }  // namespace mirror

 class Context;
 class ShadowFrame;
 class StackIndirectReferenceTable;
 class ScopedObjectAccess;
 class Thread;

 // The kind of vreg being accessed in calls to Set/GetVReg.
 enum VRegKind {
   kReferenceVReg,
   kIntVReg,
   kFloatVReg,
   kLongLoVReg,
   kLongHiVReg,
   kDoubleLoVReg,
   kDoubleHiVReg,
   kConstant,
   kImpreciseConstant,
   kUndefined,
 };

 // ShadowFrame has 3 possible layouts:
 //  - portable - a unified array of VRegs and references. Precise references need GC maps.
 //  - interpreter - separate VRegs and reference arrays. References are in the reference array.
 //  - JNI - just VRegs, but where every VReg holds a reference.
 class ShadowFrame {
  public:
   // Compute size of ShadowFrame in bytes.
   static size_t ComputeSize(uint32_t num_vregs) {
     return sizeof(ShadowFrame) + (sizeof(uint32_t) * num_vregs) +
            (sizeof(mirror::Object*) * num_vregs);
   }

   // Create ShadowFrame in heap for deoptimization.
   static ShadowFrame* Create(uint32_t num_vregs, ShadowFrame* link,
                              mirror::AbstractMethod* method, uint32_t dex_pc) {
     uint8_t* memory = new uint8_t[ComputeSize(num_vregs)];
     ShadowFrame* sf = new (memory) ShadowFrame(num_vregs, link, method, dex_pc, true);
     return sf;
   }

   // Create ShadowFrame for interpreter using provided memory.
   static ShadowFrame* Create(uint32_t num_vregs, ShadowFrame* link,
                              mirror::AbstractMethod* method, uint32_t dex_pc, void* memory) {
     ShadowFrame* sf = new (memory) ShadowFrame(num_vregs, link, method, dex_pc, true);
     return sf;
   }
   ~ShadowFrame() {}

   bool HasReferenceArray() const {
 #if defined(ART_USE_PORTABLE_COMPILER)
     return (number_of_vregs_ & kHasReferenceArray) != 0;
 #else
     return true;
 #endif
   }

   uint32_t NumberOfVRegs() const {
 #if defined(ART_USE_PORTABLE_COMPILER)
     return number_of_vregs_ & ~kHasReferenceArray;
 #else
     return number_of_vregs_;
 #endif
   }

   void SetNumberOfVRegs(uint32_t number_of_vregs) {
 #if defined(ART_USE_PORTABLE_COMPILER)
     number_of_vregs_ = number_of_vregs | (number_of_vregs_ & kHasReferenceArray);
 #else
     UNUSED(number_of_vregs);
     UNIMPLEMENTED(FATAL) << "Should only be called when portable is enabled";
 #endif
   }

   uint32_t GetDexPC() const {
     return dex_pc_;
   }

   void SetDexPC(uint32_t dex_pc) {
     dex_pc_ = dex_pc;
   }

   ShadowFrame* GetLink() const {
     return link_;
   }

   void SetLink(ShadowFrame* frame) {
     DCHECK_NE(this, frame);
     link_ = frame;
   }

   int32_t GetVReg(size_t i) const {
     DCHECK_LT(i, NumberOfVRegs());
     const uint32_t* vreg = &vregs_[i];
     return *reinterpret_cast<const int32_t*>(vreg);
   }

   float GetVRegFloat(size_t i) const {
     DCHECK_LT(i, NumberOfVRegs());
     // NOTE: Strict-aliasing?
     const uint32_t* vreg = &vregs_[i];
     return *reinterpret_cast<const float*>(vreg);
   }

   int64_t GetVRegLong(size_t i) const {
     DCHECK_LT(i, NumberOfVRegs());
     const uint32_t* vreg = &vregs_[i];
     return *reinterpret_cast<const int64_t*>(vreg);
   }

   double GetVRegDouble(size_t i) const {
     DCHECK_LT(i, NumberOfVRegs());
     const uint32_t* vreg = &vregs_[i];
     return *reinterpret_cast<const double*>(vreg);
   }

   mirror::Object* GetVRegReference(size_t i) const {
     DCHECK_LT(i, NumberOfVRegs());
     if (HasReferenceArray()) {
       return References()[i];
     } else {
       const uint32_t* vreg = &vregs_[i];
       return *reinterpret_cast<mirror::Object* const*>(vreg);
     }
   }

   // Get view of vregs as range of consecutive arguments starting at i.
   uint32_t* GetVRegArgs(size_t i) {
     return &vregs_[i];
   }

   void SetVReg(size_t i, int32_t val) {
     DCHECK_LT(i, NumberOfVRegs());
     uint32_t* vreg = &vregs_[i];
     *reinterpret_cast<int32_t*>(vreg) = val;
   }

   void SetVRegFloat(size_t i, float val) {
     DCHECK_LT(i, NumberOfVRegs());
     uint32_t* vreg = &vregs_[i];
     *reinterpret_cast<float*>(vreg) = val;
   }

   void SetVRegLong(size_t i, int64_t val) {
     DCHECK_LT(i, NumberOfVRegs());
     uint32_t* vreg = &vregs_[i];
     *reinterpret_cast<int64_t*>(vreg) = val;
   }

   void SetVRegDouble(size_t i, double val) {
     DCHECK_LT(i, NumberOfVRegs());
     uint32_t* vreg = &vregs_[i];
     *reinterpret_cast<double*>(vreg) = val;
   }

   void SetVRegReference(size_t i, mirror::Object* val) {
     DCHECK_LT(i, NumberOfVRegs());
     uint32_t* vreg = &vregs_[i];
     *reinterpret_cast<mirror::Object**>(vreg) = val;
     if (HasReferenceArray()) {
       References()[i] = val;
     }
   }

   mirror::AbstractMethod* GetMethod() const {
     DCHECK_NE(method_, static_cast<void*>(NULL));
     return method_;
   }

   mirror::Object* GetThisObject() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   mirror::Object* GetThisObject(uint16_t num_ins) const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   ThrowLocation GetCurrentLocationForThrow() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   void SetMethod(mirror::AbstractMethod* method) {
 #if defined(ART_USE_PORTABLE_COMPILER)
     DCHECK_NE(method, static_cast<void*>(NULL));
     method_ = method;
 #else
     UNUSED(method);
     UNIMPLEMENTED(FATAL) << "Should only be called when portable is enabled";
 #endif
   }

   bool Contains(mirror::Object** shadow_frame_entry_obj) const {
     if (HasReferenceArray()) {
       return ((&References()[0] <= shadow_frame_entry_obj) &&
               (shadow_frame_entry_obj <= (&References()[NumberOfVRegs() - 1])));
     } else {
       uint32_t* shadow_frame_entry = reinterpret_cast<uint32_t*>(shadow_frame_entry_obj);
       return ((&vregs_[0] <= shadow_frame_entry) &&
               (shadow_frame_entry <= (&vregs_[NumberOfVRegs() - 1])));
     }
   }

   static size_t LinkOffset() {
     return OFFSETOF_MEMBER(ShadowFrame, link_);
   }

   static size_t MethodOffset() {
     return OFFSETOF_MEMBER(ShadowFrame, method_);
   }

   static size_t DexPCOffset() {
     return OFFSETOF_MEMBER(ShadowFrame, dex_pc_);
   }

   static size_t NumberOfVRegsOffset() {
     return OFFSETOF_MEMBER(ShadowFrame, number_of_vregs_);
   }

   static size_t VRegsOffset() {
     return OFFSETOF_MEMBER(ShadowFrame, vregs_);
   }

  private:
   ShadowFrame(uint32_t num_vregs, ShadowFrame* link, mirror::AbstractMethod* method,
               uint32_t dex_pc, bool has_reference_array)
       : number_of_vregs_(num_vregs), link_(link), method_(method), dex_pc_(dex_pc) {
     if (has_reference_array) {
 #if defined(ART_USE_PORTABLE_COMPILER)
       CHECK_LT(num_vregs, static_cast<uint32_t>(kHasReferenceArray));
       number_of_vregs_ |= kHasReferenceArray;
 #endif
       memset(vregs_, 0, num_vregs * (sizeof(uint32_t) + sizeof(mirror::Object*)));
     } else {
       memset(vregs_, 0, num_vregs * sizeof(uint32_t));
     }
   }

   mirror::Object* const* References() const {
     DCHECK(HasReferenceArray());
     const uint32_t* vreg_end = &vregs_[NumberOfVRegs()];
     return reinterpret_cast<mirror::Object* const*>(vreg_end);
   }

   mirror::Object** References() {
     return const_cast<mirror::Object**>(const_cast<const ShadowFrame*>(this)->References());
   }

 #if defined(ART_USE_PORTABLE_COMPILER)
   enum ShadowFrameFlag {
     kHasReferenceArray = 1ul << 31
   };
   // TODO: make const in the portable case.
   uint32_t number_of_vregs_;
 #else
   const uint32_t number_of_vregs_;
 #endif
   // Link to previous shadow frame or NULL.
   ShadowFrame* link_;
 #if defined(ART_USE_PORTABLE_COMPILER)
   // TODO: make const in the portable case.
   mirror::AbstractMethod* method_;
 #else
   mirror::AbstractMethod* const method_;
 #endif
   uint32_t dex_pc_;
   uint32_t vregs_[0];

   DISALLOW_IMPLICIT_CONSTRUCTORS(ShadowFrame);
 };

 // The managed stack is used to record fragments of managed code stacks. Managed code stacks
 // may either be shadow frames or lists of frames using fixed frame sizes. Transition records are
 // necessary for transitions between code using different frame layouts and transitions into native
 // code.
 class PACKED(4) ManagedStack {
  public:
   ManagedStack()
       : link_(NULL), top_shadow_frame_(NULL), top_quick_frame_(NULL), top_quick_frame_pc_(0) {}

   void PushManagedStackFragment(ManagedStack* fragment) {
     // Copy this top fragment into given fragment.
     memcpy(fragment, this, sizeof(ManagedStack));
     // Clear this fragment, which has become the top.
     memset(this, 0, sizeof(ManagedStack));
     // Link our top fragment onto the given fragment.
     link_ = fragment;
   }

   void PopManagedStackFragment(const ManagedStack& fragment) {
     DCHECK(&fragment == link_);
     // Copy this given fragment back to the top.
     memcpy(this, &fragment, sizeof(ManagedStack));
   }

   ManagedStack* GetLink() const {
     return link_;
   }

   mirror::AbstractMethod** GetTopQuickFrame() const {
     return top_quick_frame_;
   }

   void SetTopQuickFrame(mirror::AbstractMethod** top) {
     DCHECK(top_shadow_frame_ == NULL);
     top_quick_frame_ = top;
   }

   uintptr_t GetTopQuickFramePc() const {
     return top_quick_frame_pc_;
   }

   void SetTopQuickFramePc(uintptr_t pc) {
     DCHECK(top_shadow_frame_ == NULL);
     top_quick_frame_pc_ = pc;
   }

   static size_t TopQuickFrameOffset() {
     return OFFSETOF_MEMBER(ManagedStack, top_quick_frame_);
   }

   static size_t TopQuickFramePcOffset() {
     return OFFSETOF_MEMBER(ManagedStack, top_quick_frame_pc_);
   }

   ShadowFrame* PushShadowFrame(ShadowFrame* new_top_frame) {
     DCHECK(top_quick_frame_ == NULL);
     ShadowFrame* old_frame = top_shadow_frame_;
     top_shadow_frame_ = new_top_frame;
     new_top_frame->SetLink(old_frame);
     return old_frame;
   }

   ShadowFrame* PopShadowFrame() {
     DCHECK(top_quick_frame_ == NULL);
     CHECK(top_shadow_frame_ != NULL);
     ShadowFrame* frame = top_shadow_frame_;
     top_shadow_frame_ = frame->GetLink();
     return frame;
   }

   ShadowFrame* GetTopShadowFrame() const {
     return top_shadow_frame_;
   }

   void SetTopShadowFrame(ShadowFrame* top) {
     DCHECK(top_quick_frame_ == NULL);
     top_shadow_frame_ = top;
   }

   static size_t TopShadowFrameOffset() {
     return OFFSETOF_MEMBER(ManagedStack, top_shadow_frame_);
   }

   size_t NumJniShadowFrameReferences() const;

   bool ShadowFramesContain(mirror::Object** shadow_frame_entry) const;

  private:
   ManagedStack* link_;
   ShadowFrame* top_shadow_frame_;
   mirror::AbstractMethod** top_quick_frame_;
   uintptr_t top_quick_frame_pc_;
 };

 class StackVisitor {
  protected:
   StackVisitor(Thread* thread, Context* context) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

  public:
   virtual ~StackVisitor() {}

   // Return 'true' if we should continue to visit more frames, 'false' to stop.
   virtual bool VisitFrame() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) = 0;

   void WalkStack(bool include_transitions = false)
       SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   mirror::AbstractMethod* GetMethod() const {
     if (cur_shadow_frame_ != NULL) {
       return cur_shadow_frame_->GetMethod();
     } else if (cur_quick_frame_ != NULL) {
       return *cur_quick_frame_;
     } else {
       return NULL;
     }
   }

   bool IsShadowFrame() const {
     return cur_shadow_frame_ != NULL;
   }

   uint32_t GetDexPc() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   mirror::Object* GetThisObject() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   size_t GetNativePcOffset() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   uintptr_t* CalleeSaveAddress(int num, size_t frame_size) const {
     // Callee saves are held at the top of the frame
     DCHECK(GetMethod() != NULL);
     byte* save_addr =
         reinterpret_cast<byte*>(cur_quick_frame_) + frame_size - ((num + 1) * kPointerSize);
 #if defined(__i386__)
     save_addr -= kPointerSize;  // account for return address
 #endif
     return reinterpret_cast<uintptr_t*>(save_addr);
   }

   // Returns the height of the stack in the managed stack frames, including transitions.
   size_t GetFrameHeight() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) {
     return GetNumFrames() - cur_depth_ - 1;
   }

   // Returns a frame ID for JDWP use, starting from 1.
   size_t GetFrameId() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) {
     return GetFrameHeight() + 1;
   }

   size_t GetNumFrames() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) {
     if (num_frames_ == 0) {
       num_frames_ = ComputeNumFrames(thread_);
     }
     return num_frames_;
   }

   uint32_t GetVReg(mirror::AbstractMethod* m, uint16_t vreg, VRegKind kind) const
       SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   void SetVReg(mirror::AbstractMethod* m, uint16_t vreg, uint32_t new_value, VRegKind kind)
       SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   uintptr_t GetGPR(uint32_t reg) const;
   void SetGPR(uint32_t reg, uintptr_t value);

   uint32_t GetVReg(mirror::AbstractMethod** cur_quick_frame, const DexFile::CodeItem* code_item,
                    uint32_t core_spills, uint32_t fp_spills, size_t frame_size,
                    uint16_t vreg) const {
     int offset = GetVRegOffset(code_item, core_spills, fp_spills, frame_size, vreg);
     DCHECK_EQ(cur_quick_frame, GetCurrentQuickFrame());
     byte* vreg_addr = reinterpret_cast<byte*>(cur_quick_frame) + offset;
     return *reinterpret_cast<uint32_t*>(vreg_addr);
   }

   uintptr_t GetReturnPc() const;

   void SetReturnPc(uintptr_t new_ret_pc);

   /*
    * Return sp-relative offset for a Dalvik virtual register, compiler
    * spill or Method* in bytes using Method*.
    * Note that (reg >= 0) refers to a Dalvik register, (reg == -2)
    * denotes Method* and (reg <= -3) denotes a compiler temp.
    *
    *     +------------------------+
    *     | IN[ins-1]              |  {Note: resides in caller's frame}
    *     |       .                |
    *     | IN[0]                  |
    *     | caller's Method*       |
    *     +========================+  {Note: start of callee's frame}
    *     | core callee-save spill |  {variable sized}
    *     +------------------------+
    *     | fp callee-save spill   |
    *     +------------------------+
    *     | filler word            |  {For compatibility, if V[locals-1] used as wide
    *     +------------------------+
    *     | V[locals-1]            |
    *     | V[locals-2]            |
    *     |      .                 |
    *     |      .                 |  ... (reg == 2)
    *     | V[1]                   |  ... (reg == 1)
    *     | V[0]                   |  ... (reg == 0) <---- "locals_start"
    *     +------------------------+
    *     | Compiler temps         |  ... (reg == -2)
    *     |                        |  ... (reg == -3)
    *     |                        |  ... (reg == -4)
    *     +------------------------+
    *     | stack alignment padding|  {0 to (kStackAlignWords-1) of padding}
    *     +------------------------+
    *     | OUT[outs-1]            |
    *     | OUT[outs-2]            |
    *     |       .                |
    *     | OUT[0]                 |
    *     | curMethod*             |  ... (reg == -1) <<== sp, 16-byte aligned
    *     +========================+
    */
   static int GetVRegOffset(const DexFile::CodeItem* code_item,
                            uint32_t core_spills, uint32_t fp_spills,
                            size_t frame_size, int reg) {
     DCHECK_EQ(frame_size & (kStackAlignment - 1), 0U);
     int num_spills = __builtin_popcount(core_spills) + __builtin_popcount(fp_spills) + 1; // Filler.
     int num_ins = code_item->ins_size_;
     int num_regs = code_item->registers_size_ - num_ins;
     int locals_start = frame_size - ((num_spills + num_regs) * sizeof(uint32_t));
     if (reg == -2) {
       return 0;  // Method*
     } else if (reg <= -3) {
       return locals_start - ((reg + 1) * sizeof(uint32_t));  // Compiler temp.
     } else if (reg < num_regs) {
       return locals_start + (reg * sizeof(uint32_t));        // Dalvik local reg.
     } else {
       return frame_size + ((reg - num_regs) * sizeof(uint32_t)) + sizeof(uint32_t); // Dalvik in.
     }
   }

   uintptr_t GetCurrentQuickFramePc() const {
     return cur_quick_frame_pc_;
   }

   mirror::AbstractMethod** GetCurrentQuickFrame() const {
     return cur_quick_frame_;
   }

   ShadowFrame* GetCurrentShadowFrame() const {
     return cur_shadow_frame_;
   }

   StackIndirectReferenceTable* GetCurrentSirt() const {
     mirror::AbstractMethod** sp = GetCurrentQuickFrame();
     ++sp; // Skip Method*; SIRT comes next;
     return reinterpret_cast<StackIndirectReferenceTable*>(sp);
   }

   std::string DescribeLocation() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   static size_t ComputeNumFrames(Thread* thread) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   static void DescribeStack(Thread* thread) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

  private:
   instrumentation::InstrumentationStackFrame GetInstrumentationStackFrame(uint32_t depth) const;

   void SanityCheckFrame() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

   Thread* const thread_;
   ShadowFrame* cur_shadow_frame_;
   mirror::AbstractMethod** cur_quick_frame_;
   uintptr_t cur_quick_frame_pc_;
   // Lazily computed, number of frames in the stack.
   size_t num_frames_;
   // Depth of the frame we're currently at.
   size_t cur_depth_;

  protected:
   Context* const context_;
 };

 class VmapTable {
  public:
   explicit VmapTable(const uint16_t* table) : table_(table) {
   }

   uint16_t operator[](size_t i) const {
     return table_[i + 1];
   }

   size_t size() const {
     return table_[0];
   }

   // Is the dex register 'vreg' in the context or on the stack? Should not be called when the
   // 'kind' is unknown or constant.
   bool IsInContext(size_t vreg, uint32_t& vmap_offset, VRegKind kind) const {
     DCHECK(kind == kReferenceVReg || kind == kIntVReg || kind == kFloatVReg ||
            kind == kLongLoVReg || kind == kLongHiVReg || kind == kDoubleLoVReg ||
            kind == kDoubleHiVReg || kind == kImpreciseConstant);
     vmap_offset = 0xEBAD0FF5;
     // TODO: take advantage of the registers being ordered
     // TODO: we treat kImpreciseConstant as an integer below, need to ensure that such values
     //       are never promoted to floating point registers.
     bool is_float = (kind == kFloatVReg) || (kind == kDoubleLoVReg) || (kind == kDoubleHiVReg);
     bool in_floats = false;
     for (size_t i = 0; i < size(); ++i) {
       // Stop if we find what we are are looking for.
       if ((table_[i + 1] == vreg) && (in_floats == is_float)) {
         vmap_offset = i;
         return true;
       }
       // 0xffff is the marker for LR (return PC on x86), following it are spilled float registers.
       if (table_[i + 1] == 0xffff) {
         in_floats = true;
       }
     }
     return false;
   }

   // Compute the register number that corresponds to the entry in the vmap (vmap_offset, computed
   // by IsInContext above). If the kind is floating point then the result will be a floating point
   // register number, otherwise it will be an integer register number.
   uint32_t ComputeRegister(uint32_t spill_mask, uint32_t vmap_offset, VRegKind kind) const {
     // Compute the register we need to load from the context.
     DCHECK(kind == kReferenceVReg || kind == kIntVReg || kind == kFloatVReg ||
            kind == kLongLoVReg || kind == kLongHiVReg || kind == kDoubleLoVReg ||
            kind == kDoubleHiVReg || kind == kImpreciseConstant);
     // TODO: we treat kImpreciseConstant as an integer below, need to ensure that such values
     //       are never promoted to floating point registers.
     bool is_float = (kind == kFloatVReg) || (kind == kDoubleLoVReg) || (kind == kDoubleHiVReg);
     uint32_t matches = 0;
     if (is_float) {
       while (table_[matches] != 0xffff) {
         matches++;
       }
     }
     CHECK_LT(vmap_offset - matches, static_cast<uint32_t>(__builtin_popcount(spill_mask)));
     uint32_t spill_shifts = 0;
     while (matches != (vmap_offset + 1)) {
       DCHECK_NE(spill_mask, 0u);
       matches += spill_mask & 1;  // Add 1 if the low bit is set
       spill_mask >>= 1;
       spill_shifts++;
     }
     spill_shifts--;  // wind back one as we want the last match
     return spill_shifts;
   }

  private:
   const uint16_t* table_;
 };

 }  // namespace art

 #endif  // ART_RUNTIME_STACK_H_
	/*
	* 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.
	*/

	#ifndef ART_RUNTIME_STACK_H_
	#define ART_RUNTIME_STACK_H_

	#include "dex_file.h"
	#include "instrumentation.h"
	#include "base/macros.h"
	#include "oat/runtime/context.h"

	#include <stdint.h>
	#include <string>

	namespace art {

	namespace mirror {
	class AbstractMethod;
	class Object;
	} // namespace mirror

	class Context;
	class ShadowFrame;
	class StackIndirectReferenceTable;
	class ScopedObjectAccess;
	class Thread;

	// The kind of vreg being accessed in calls to Set/GetVReg.
	enum VRegKind {
	kReferenceVReg,
	kIntVReg,
	kFloatVReg,
	kLongLoVReg,
	kLongHiVReg,
	kDoubleLoVReg,
	kDoubleHiVReg,
	kConstant,
	kImpreciseConstant,
	kUndefined,
	};

	// ShadowFrame has 3 possible layouts:
	// - portable - a unified array of VRegs and references. Precise references need GC maps.
	// - interpreter - separate VRegs and reference arrays. References are in the reference array.
	// - JNI - just VRegs, but where every VReg holds a reference.
	class ShadowFrame {
	public:
	// Compute size of ShadowFrame in bytes.
	static size_t ComputeSize(uint32_t num_vregs) {
	return sizeof(ShadowFrame) + (sizeof(uint32_t) * num_vregs) +
	(sizeof(mirror::Object) num_vregs);
	}

	// Create ShadowFrame in heap for deoptimization.
	static ShadowFrame* Create(uint32_t num_vregs, ShadowFrame* link,
	mirror::AbstractMethod* method, uint32_t dex_pc) {
	uint8_t* memory = new uint8_t[ComputeSize(num_vregs)];
	ShadowFrame* sf = new (memory) ShadowFrame(num_vregs, link, method, dex_pc, true);
	return sf;
	}

	// Create ShadowFrame for interpreter using provided memory.
	static ShadowFrame* Create(uint32_t num_vregs, ShadowFrame* link,
	mirror::AbstractMethod* method, uint32_t dex_pc, void* memory) {
	ShadowFrame* sf = new (memory) ShadowFrame(num_vregs, link, method, dex_pc, true);
	return sf;
	}
	~ShadowFrame() {}

	bool HasReferenceArray() const {
	#if defined(ART_USE_PORTABLE_COMPILER)
	return (number_of_vregs_ & kHasReferenceArray) != 0;
	#else
	return true;
	#endif
	}

	uint32_t NumberOfVRegs() const {
	#if defined(ART_USE_PORTABLE_COMPILER)
	return number_of_vregs_ & ~kHasReferenceArray;
	#else
	return number_of_vregs_;
	#endif
	}

	void SetNumberOfVRegs(uint32_t number_of_vregs) {
	#if defined(ART_USE_PORTABLE_COMPILER)
	number_of_vregs_ = number_of_vregs \| (number_of_vregs_ & kHasReferenceArray);
	#else
	UNUSED(number_of_vregs);
	UNIMPLEMENTED(FATAL) << "Should only be called when portable is enabled";
	#endif
	}

	uint32_t GetDexPC() const {
	return dex_pc_;
	}

	void SetDexPC(uint32_t dex_pc) {
	dex_pc_ = dex_pc;
	}

	ShadowFrame* GetLink() const {
	return link_;
	}

	void SetLink(ShadowFrame* frame) {
	DCHECK_NE(this, frame);
	link_ = frame;
	}

	int32_t GetVReg(size_t i) const {
	DCHECK_LT(i, NumberOfVRegs());
	const uint32_t* vreg = &vregs_[i];
	return reinterpret_cast<const int32_t>(vreg);
	}

	float GetVRegFloat(size_t i) const {
	DCHECK_LT(i, NumberOfVRegs());
	// NOTE: Strict-aliasing?
	const uint32_t* vreg = &vregs_[i];
	return reinterpret_cast<const float>(vreg);
	}

	int64_t GetVRegLong(size_t i) const {
	DCHECK_LT(i, NumberOfVRegs());
	const uint32_t* vreg = &vregs_[i];
	return reinterpret_cast<const int64_t>(vreg);
	}

	double GetVRegDouble(size_t i) const {
	DCHECK_LT(i, NumberOfVRegs());
	const uint32_t* vreg = &vregs_[i];
	return reinterpret_cast<const double>(vreg);
	}

	mirror::Object* GetVRegReference(size_t i) const {
	DCHECK_LT(i, NumberOfVRegs());
	if (HasReferenceArray()) {
	return References()[i];
	} else {
	const uint32_t* vreg = &vregs_[i];
	return reinterpret_cast<mirror::Object const*>(vreg);
	}
	}

	// Get view of vregs as range of consecutive arguments starting at i.
	uint32_t* GetVRegArgs(size_t i) {
	return &vregs_[i];
	}

	void SetVReg(size_t i, int32_t val) {
	DCHECK_LT(i, NumberOfVRegs());
	uint32_t* vreg = &vregs_[i];
	reinterpret_cast<int32_t>(vreg) = val;
	}

	void SetVRegFloat(size_t i, float val) {
	DCHECK_LT(i, NumberOfVRegs());
	uint32_t* vreg = &vregs_[i];
	reinterpret_cast<float>(vreg) = val;
	}

	void SetVRegLong(size_t i, int64_t val) {
	DCHECK_LT(i, NumberOfVRegs());
	uint32_t* vreg = &vregs_[i];
	reinterpret_cast<int64_t>(vreg) = val;
	}

	void SetVRegDouble(size_t i, double val) {
	DCHECK_LT(i, NumberOfVRegs());
	uint32_t* vreg = &vregs_[i];
	reinterpret_cast<double>(vreg) = val;
	}

	void SetVRegReference(size_t i, mirror::Object* val) {
	DCHECK_LT(i, NumberOfVRegs());
	uint32_t* vreg = &vregs_[i];
	reinterpret_cast<mirror::Object*>(vreg) = val;
	if (HasReferenceArray()) {
	References()[i] = val;
	}
	}

	mirror::AbstractMethod* GetMethod() const {
	DCHECK_NE(method_, static_cast<void*>(NULL));
	return method_;
	}

	mirror::Object* GetThisObject() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	mirror::Object* GetThisObject(uint16_t num_ins) const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	ThrowLocation GetCurrentLocationForThrow() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	void SetMethod(mirror::AbstractMethod* method) {
	#if defined(ART_USE_PORTABLE_COMPILER)
	DCHECK_NE(method, static_cast<void*>(NULL));
	method_ = method;
	#else
	UNUSED(method);
	UNIMPLEMENTED(FATAL) << "Should only be called when portable is enabled";
	#endif
	}

	bool Contains(mirror::Object** shadow_frame_entry_obj) const {
	if (HasReferenceArray()) {
	return ((&References()[0] <= shadow_frame_entry_obj) &&
	(shadow_frame_entry_obj <= (&References()[NumberOfVRegs() - 1])));
	} else {
	uint32_t* shadow_frame_entry = reinterpret_cast<uint32_t*>(shadow_frame_entry_obj);
	return ((&vregs_[0] <= shadow_frame_entry) &&
	(shadow_frame_entry <= (&vregs_[NumberOfVRegs() - 1])));
	}
	}

	static size_t LinkOffset() {
	return OFFSETOF_MEMBER(ShadowFrame, link_);
	}

	static size_t MethodOffset() {
	return OFFSETOF_MEMBER(ShadowFrame, method_);
	}

	static size_t DexPCOffset() {
	return OFFSETOF_MEMBER(ShadowFrame, dex_pc_);
	}

	static size_t NumberOfVRegsOffset() {
	return OFFSETOF_MEMBER(ShadowFrame, number_of_vregs_);
	}

	static size_t VRegsOffset() {
	return OFFSETOF_MEMBER(ShadowFrame, vregs_);
	}

	private:
	ShadowFrame(uint32_t num_vregs, ShadowFrame* link, mirror::AbstractMethod* method,
	uint32_t dex_pc, bool has_reference_array)
	: number_of_vregs_(num_vregs), link_(link), method_(method), dex_pc_(dex_pc) {
	if (has_reference_array) {
	#if defined(ART_USE_PORTABLE_COMPILER)
	CHECK_LT(num_vregs, static_cast<uint32_t>(kHasReferenceArray));
	number_of_vregs_ \|= kHasReferenceArray;
	#endif
	memset(vregs_, 0, num_vregs * (sizeof(uint32_t) + sizeof(mirror::Object*)));
	} else {
	memset(vregs_, 0, num_vregs * sizeof(uint32_t));
	}
	}

	mirror::Object* const* References() const {
	DCHECK(HasReferenceArray());
	const uint32_t* vreg_end = &vregs_[NumberOfVRegs()];
	return reinterpret_cast<mirror::Object* const*>(vreg_end);
	}

	mirror::Object** References() {
	return const_cast<mirror::Object*>(const_cast<const ShadowFrame>(this)->References());
	}

	#if defined(ART_USE_PORTABLE_COMPILER)
	enum ShadowFrameFlag {
	kHasReferenceArray = 1ul << 31
	};
	// TODO: make const in the portable case.
	uint32_t number_of_vregs_;
	#else
	const uint32_t number_of_vregs_;
	#endif
	// Link to previous shadow frame or NULL.
	ShadowFrame* link_;
	#if defined(ART_USE_PORTABLE_COMPILER)
	// TODO: make const in the portable case.
	mirror::AbstractMethod* method_;
	#else
	mirror::AbstractMethod* const method_;
	#endif
	uint32_t dex_pc_;
	uint32_t vregs_[0];

	DISALLOW_IMPLICIT_CONSTRUCTORS(ShadowFrame);
	};

	// The managed stack is used to record fragments of managed code stacks. Managed code stacks
	// may either be shadow frames or lists of frames using fixed frame sizes. Transition records are
	// necessary for transitions between code using different frame layouts and transitions into native
	// code.
	class PACKED(4) ManagedStack {
	public:
	ManagedStack()
	: link_(NULL), top_shadow_frame_(NULL), top_quick_frame_(NULL), top_quick_frame_pc_(0) {}

	void PushManagedStackFragment(ManagedStack* fragment) {
	// Copy this top fragment into given fragment.
	memcpy(fragment, this, sizeof(ManagedStack));
	// Clear this fragment, which has become the top.
	memset(this, 0, sizeof(ManagedStack));
	// Link our top fragment onto the given fragment.
	link_ = fragment;
	}

	void PopManagedStackFragment(const ManagedStack& fragment) {
	DCHECK(&fragment == link_);
	// Copy this given fragment back to the top.
	memcpy(this, &fragment, sizeof(ManagedStack));
	}

	ManagedStack* GetLink() const {
	return link_;
	}

	mirror::AbstractMethod** GetTopQuickFrame() const {
	return top_quick_frame_;
	}

	void SetTopQuickFrame(mirror::AbstractMethod** top) {
	DCHECK(top_shadow_frame_ == NULL);
	top_quick_frame_ = top;
	}

	uintptr_t GetTopQuickFramePc() const {
	return top_quick_frame_pc_;
	}

	void SetTopQuickFramePc(uintptr_t pc) {
	DCHECK(top_shadow_frame_ == NULL);
	top_quick_frame_pc_ = pc;
	}

	static size_t TopQuickFrameOffset() {
	return OFFSETOF_MEMBER(ManagedStack, top_quick_frame_);
	}

	static size_t TopQuickFramePcOffset() {
	return OFFSETOF_MEMBER(ManagedStack, top_quick_frame_pc_);
	}

	ShadowFrame* PushShadowFrame(ShadowFrame* new_top_frame) {
	DCHECK(top_quick_frame_ == NULL);
	ShadowFrame* old_frame = top_shadow_frame_;
	top_shadow_frame_ = new_top_frame;
	new_top_frame->SetLink(old_frame);
	return old_frame;
	}

	ShadowFrame* PopShadowFrame() {
	DCHECK(top_quick_frame_ == NULL);
	CHECK(top_shadow_frame_ != NULL);
	ShadowFrame* frame = top_shadow_frame_;
	top_shadow_frame_ = frame->GetLink();
	return frame;
	}

	ShadowFrame* GetTopShadowFrame() const {
	return top_shadow_frame_;
	}

	void SetTopShadowFrame(ShadowFrame* top) {
	DCHECK(top_quick_frame_ == NULL);
	top_shadow_frame_ = top;
	}

	static size_t TopShadowFrameOffset() {
	return OFFSETOF_MEMBER(ManagedStack, top_shadow_frame_);
	}

	size_t NumJniShadowFrameReferences() const;

	bool ShadowFramesContain(mirror::Object** shadow_frame_entry) const;

	private:
	ManagedStack* link_;
	ShadowFrame* top_shadow_frame_;
	mirror::AbstractMethod** top_quick_frame_;
	uintptr_t top_quick_frame_pc_;
	};

	class StackVisitor {
	protected:
	StackVisitor(Thread* thread, Context* context) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	public:
	virtual ~StackVisitor() {}

	// Return 'true' if we should continue to visit more frames, 'false' to stop.
	virtual bool VisitFrame() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) = 0;

	void WalkStack(bool include_transitions = false)
	SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	mirror::AbstractMethod* GetMethod() const {
	if (cur_shadow_frame_ != NULL) {
	return cur_shadow_frame_->GetMethod();
	} else if (cur_quick_frame_ != NULL) {
	return *cur_quick_frame_;
	} else {
	return NULL;
	}
	}

	bool IsShadowFrame() const {
	return cur_shadow_frame_ != NULL;
	}

	uint32_t GetDexPc() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	mirror::Object* GetThisObject() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	size_t GetNativePcOffset() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	uintptr_t* CalleeSaveAddress(int num, size_t frame_size) const {
	// Callee saves are held at the top of the frame
	DCHECK(GetMethod() != NULL);
	byte* save_addr =
	reinterpret_cast<byte>(cur_quick_frame_) + frame_size - ((num + 1) kPointerSize);
	#if defined(__i386__)
	save_addr -= kPointerSize; // account for return address
	#endif
	return reinterpret_cast<uintptr_t*>(save_addr);
	}

	// Returns the height of the stack in the managed stack frames, including transitions.
	size_t GetFrameHeight() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) {
	return GetNumFrames() - cur_depth_ - 1;
	}

	// Returns a frame ID for JDWP use, starting from 1.
	size_t GetFrameId() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) {
	return GetFrameHeight() + 1;
	}

	size_t GetNumFrames() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) {
	if (num_frames_ == 0) {
	num_frames_ = ComputeNumFrames(thread_);
	}
	return num_frames_;
	}

	uint32_t GetVReg(mirror::AbstractMethod* m, uint16_t vreg, VRegKind kind) const
	SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	void SetVReg(mirror::AbstractMethod* m, uint16_t vreg, uint32_t new_value, VRegKind kind)
	SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	uintptr_t GetGPR(uint32_t reg) const;
	void SetGPR(uint32_t reg, uintptr_t value);

	uint32_t GetVReg(mirror::AbstractMethod** cur_quick_frame, const DexFile::CodeItem* code_item,
	uint32_t core_spills, uint32_t fp_spills, size_t frame_size,
	uint16_t vreg) const {
	int offset = GetVRegOffset(code_item, core_spills, fp_spills, frame_size, vreg);
	DCHECK_EQ(cur_quick_frame, GetCurrentQuickFrame());
	byte* vreg_addr = reinterpret_cast<byte*>(cur_quick_frame) + offset;
	return reinterpret_cast<uint32_t>(vreg_addr);
	}

	uintptr_t GetReturnPc() const;

	void SetReturnPc(uintptr_t new_ret_pc);

	/*
	* Return sp-relative offset for a Dalvik virtual register, compiler
	* spill or Method* in bytes using Method*.
	* Note that (reg >= 0) refers to a Dalvik register, (reg == -2)
	* denotes Method* and (reg <= -3) denotes a compiler temp.
	*
	* +------------------------+
	* \| IN[ins-1] \| {Note: resides in caller's frame}
	* \| . \|
	* \| IN[0] \|
	* \| caller's Method* \|
	* +========================+ {Note: start of callee's frame}
	* \| core callee-save spill \| {variable sized}
	* +------------------------+
	* \| fp callee-save spill \|
	* +------------------------+
	* \| filler word \| {For compatibility, if V[locals-1] used as wide
	* +------------------------+
	* \| V[locals-1] \|
	* \| V[locals-2] \|
	* \| . \|
	* \| . \| ... (reg == 2)
	* \| V[1] \| ... (reg == 1)
	* \| V[0] \| ... (reg == 0) <---- "locals_start"
	* +------------------------+
	* \| Compiler temps \| ... (reg == -2)
	* \| \| ... (reg == -3)
	* \| \| ... (reg == -4)
	* +------------------------+
	* \| stack alignment padding\| {0 to (kStackAlignWords-1) of padding}
	* +------------------------+
	* \| OUT[outs-1] \|
	* \| OUT[outs-2] \|
	* \| . \|
	* \| OUT[0] \|
	* \| curMethod* \| ... (reg == -1) <<== sp, 16-byte aligned
	* +========================+
	*/
	static int GetVRegOffset(const DexFile::CodeItem* code_item,
	uint32_t core_spills, uint32_t fp_spills,
	size_t frame_size, int reg) {
	DCHECK_EQ(frame_size & (kStackAlignment - 1), 0U);
	int num_spills = __builtin_popcount(core_spills) + __builtin_popcount(fp_spills) + 1; // Filler.
	int num_ins = code_item->ins_size_;
	int num_regs = code_item->registers_size_ - num_ins;
	int locals_start = frame_size - ((num_spills + num_regs) * sizeof(uint32_t));
	if (reg == -2) {
	return 0; // Method*
	} else if (reg <= -3) {
	return locals_start - ((reg + 1) * sizeof(uint32_t)); // Compiler temp.
	} else if (reg < num_regs) {
	return locals_start + (reg * sizeof(uint32_t)); // Dalvik local reg.
	} else {
	return frame_size + ((reg - num_regs) * sizeof(uint32_t)) + sizeof(uint32_t); // Dalvik in.
	}
	}

	uintptr_t GetCurrentQuickFramePc() const {
	return cur_quick_frame_pc_;
	}

	mirror::AbstractMethod** GetCurrentQuickFrame() const {
	return cur_quick_frame_;
	}

	ShadowFrame* GetCurrentShadowFrame() const {
	return cur_shadow_frame_;
	}

	StackIndirectReferenceTable* GetCurrentSirt() const {
	mirror::AbstractMethod** sp = GetCurrentQuickFrame();
	++sp; // Skip Method*; SIRT comes next;
	return reinterpret_cast<StackIndirectReferenceTable*>(sp);
	}

	std::string DescribeLocation() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	static size_t ComputeNumFrames(Thread* thread) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	static void DescribeStack(Thread* thread) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	private:
	instrumentation::InstrumentationStackFrame GetInstrumentationStackFrame(uint32_t depth) const;

	void SanityCheckFrame() const SHARED_LOCKS_REQUIRED(Locks::mutator_lock_);

	Thread* const thread_;
	ShadowFrame* cur_shadow_frame_;
	mirror::AbstractMethod** cur_quick_frame_;
	uintptr_t cur_quick_frame_pc_;
	// Lazily computed, number of frames in the stack.
	size_t num_frames_;
	// Depth of the frame we're currently at.
	size_t cur_depth_;

	protected:
	Context* const context_;
	};

	class VmapTable {
	public:
	explicit VmapTable(const uint16_t* table) : table_(table) {
	}

	uint16_t operator[](size_t i) const {
	return table_[i + 1];
	}

	size_t size() const {
	return table_[0];
	}

	// Is the dex register 'vreg' in the context or on the stack? Should not be called when the
	// 'kind' is unknown or constant.
	bool IsInContext(size_t vreg, uint32_t& vmap_offset, VRegKind kind) const {
	DCHECK(kind == kReferenceVReg \|\| kind == kIntVReg \|\| kind == kFloatVReg \|\|
	kind == kLongLoVReg \|\| kind == kLongHiVReg \|\| kind == kDoubleLoVReg \|\|
	kind == kDoubleHiVReg \|\| kind == kImpreciseConstant);
	vmap_offset = 0xEBAD0FF5;
	// TODO: take advantage of the registers being ordered
	// TODO: we treat kImpreciseConstant as an integer below, need to ensure that such values
	// are never promoted to floating point registers.
	bool is_float = (kind == kFloatVReg) \|\| (kind == kDoubleLoVReg) \|\| (kind == kDoubleHiVReg);
	bool in_floats = false;
	for (size_t i = 0; i < size(); ++i) {
	// Stop if we find what we are are looking for.
	if ((table_[i + 1] == vreg) && (in_floats == is_float)) {
	vmap_offset = i;
	return true;
	}
	// 0xffff is the marker for LR (return PC on x86), following it are spilled float registers.
	if (table_[i + 1] == 0xffff) {
	in_floats = true;
	}
	}
	return false;
	}

	// Compute the register number that corresponds to the entry in the vmap (vmap_offset, computed
	// by IsInContext above). If the kind is floating point then the result will be a floating point
	// register number, otherwise it will be an integer register number.
	uint32_t ComputeRegister(uint32_t spill_mask, uint32_t vmap_offset, VRegKind kind) const {
	// Compute the register we need to load from the context.
	DCHECK(kind == kReferenceVReg \|\| kind == kIntVReg \|\| kind == kFloatVReg \|\|
	kind == kLongLoVReg \|\| kind == kLongHiVReg \|\| kind == kDoubleLoVReg \|\|
	kind == kDoubleHiVReg \|\| kind == kImpreciseConstant);
	// TODO: we treat kImpreciseConstant as an integer below, need to ensure that such values
	// are never promoted to floating point registers.
	bool is_float = (kind == kFloatVReg) \|\| (kind == kDoubleLoVReg) \|\| (kind == kDoubleHiVReg);
	uint32_t matches = 0;
	if (is_float) {
	while (table_[matches] != 0xffff) {
	matches++;
	}
	}
	CHECK_LT(vmap_offset - matches, static_cast<uint32_t>(__builtin_popcount(spill_mask)));
	uint32_t spill_shifts = 0;
	while (matches != (vmap_offset + 1)) {
	DCHECK_NE(spill_mask, 0u);
	matches += spill_mask & 1; // Add 1 if the low bit is set
	spill_mask >>= 1;
	spill_shifts++;
	}
	spill_shifts--; // wind back one as we want the last match
	return spill_shifts;
	}

	private:
	const uint16_t* table_;
	};

	} // namespace art

	#endif // ART_RUNTIME_STACK_H_