[Isolates] Merge 6700:7030 from bleeding_edge to isolates.

src/hydrogen-instructions.h

 // Copyright 2011 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
@@ skipping 30 matching lines @@
 class HEnvironment;
 class HInstruction;
 class HLoopInformation;
 class HValue;
 class LInstruction;
 class LChunkBuilder;
 
 
 #define HYDROGEN_ALL_INSTRUCTION_LIST(V)       \
   V(ArithmeticBinaryOperation)                 \
+  V(BinaryCall)                                \
   V(BinaryOperation)                           \
   V(BitwiseBinaryOperation)                    \
-  V(Call)                                      \
   V(ControlInstruction)                        \
   V(Instruction)                               \
-  V(LoadKeyed)                                 \
-  V(MaterializedLiteral)                       \
   V(Phi)                                       \
-  V(StoreKeyed)                                \
-  V(StoreNamed)                                \
+  V(UnaryCall)                                 \
   V(UnaryControlInstruction)                   \
   V(UnaryOperation)                            \
   HYDROGEN_CONCRETE_INSTRUCTION_LIST(V)
 
 
 #define HYDROGEN_CONCRETE_INSTRUCTION_LIST(V)  \
   V(AbnormalExit)                              \
   V(AccessArgumentsAt)                         \
   V(Add)                                       \
   V(ApplyArguments)                            \
@@ skipping 27 matching lines @@
   V(CompareJSObjectEq)                         \
   V(CompareMap)                                \
   V(Constant)                                  \
   V(Context)                                   \
   V(DeleteProperty)                            \
   V(Deoptimize)                                \
   V(Div)                                       \
   V(EnterInlined)                              \
   V(FixedArrayLength)                          \
   V(FunctionLiteral)                           \
+  V(GetCachedArrayIndex)                       \
   V(GlobalObject)                              \
   V(GlobalReceiver)                            \
   V(Goto)                                      \
   V(InstanceOf)                                \
   V(InstanceOfKnownGlobal)                     \
   V(IsNull)                                    \
   V(IsObject)                                  \
   V(IsSmi)                                     \
   V(IsConstructCall)                           \
   V(HasInstanceType)                           \
   V(HasCachedArrayIndex)                       \
   V(JSArrayLength)                             \
   V(ClassOfTest)                               \
   V(LeaveInlined)                              \
   V(LoadContextSlot)                           \
   V(LoadElements)                              \
   V(LoadFunctionPrototype)                     \
   V(LoadGlobal)                                \
   V(LoadKeyedFastElement)                      \
   V(LoadKeyedGeneric)                          \
   V(LoadNamedField)                            \
   V(LoadNamedGeneric)                          \
+  V(LoadPixelArrayElement)                     \
+  V(LoadPixelArrayExternalPointer)             \
   V(Mod)                                       \
   V(Mul)                                       \
   V(ObjectLiteral)                             \
   V(OsrEntry)                                  \
   V(OuterContext)                              \
   V(Parameter)                                 \
+  V(PixelArrayLength)                          \
   V(Power)                                     \
   V(PushArgument)                              \
   V(RegExpLiteral)                             \
   V(Return)                                    \
   V(Sar)                                       \
   V(Shl)                                       \
   V(Shr)                                       \
   V(Simulate)                                  \
   V(StackCheck)                                \
   V(StoreContextSlot)                          \
   V(StoreGlobal)                               \
   V(StoreKeyedFastElement)                     \
+  V(StorePixelArrayElement)                    \
   V(StoreKeyedGeneric)                         \
   V(StoreNamedField)                           \
   V(StoreNamedGeneric)                         \
   V(StringCharCodeAt)                          \
   V(StringLength)                              \
   V(Sub)                                       \
   V(Test)                                      \
   V(Throw)                                     \
   V(Typeof)                                    \
   V(TypeofIs)                                  \
   V(UnaryMathOperation)                        \
   V(UnknownOSRValue)                           \
   V(ValueOf)
 
 #define GVN_FLAG_LIST(V)                       \
   V(Calls)                                     \
   V(InobjectFields)                            \
   V(BackingStoreFields)                        \
   V(ArrayElements)                             \
+  V(PixelArrayElements)                        \
   V(GlobalVars)                                \
   V(Maps)                                      \
   V(ArrayLengths)                              \
   V(ContextSlots)                              \
   V(OsrEntries)
 
 #define DECLARE_INSTRUCTION(type)                   \
   virtual bool Is##type() const { return true; }    \
   static H##type* cast(HValue* value) {             \
     ASSERT(value->Is##type());                      \
     return reinterpret_cast<H##type*>(value);       \
   }                                                 \
   Opcode opcode() const { return HValue::k##type; }
 
 
 #define DECLARE_CONCRETE_INSTRUCTION(type, mnemonic)              \
   virtual LInstruction* CompileToLithium(LChunkBuilder* builder); \
   virtual const char* Mnemonic() const { return mnemonic; }       \
   DECLARE_INSTRUCTION(type)
 
 
-
-template<int kSize>
-class HOperandVector : public EmbeddedVector<HValue*, kSize> {
- public:
-  HOperandVector() : EmbeddedVector<HValue*, kSize>(NULL) { }
-};
-
-
 class Range: public ZoneObject {
  public:
   Range() : lower_(kMinInt),
             upper_(kMaxInt),
             next_(NULL),
             can_be_minus_zero_(false) { }
 
   Range(int32_t lower, int32_t upper)
       : lower_(lower), upper_(upper), next_(NULL), can_be_minus_zero_(false) { }
 
@@ skipping 76 matching lines @@
 };
 
 
 class Representation {
  public:
   enum Kind {
     kNone,
     kTagged,
     kDouble,
     kInteger32,
+    kExternal,
     kNumRepresentations
   };
 
   Representation() : kind_(kNone) { }
 
   static Representation None() { return Representation(kNone); }
   static Representation Tagged() { return Representation(kTagged); }
   static Representation Integer32() { return Representation(kInteger32); }
   static Representation Double() { return Representation(kDouble); }
+  static Representation External() { return Representation(kExternal); }
 
-  bool Equals(const Representation& other) const {
+  bool Equals(const Representation& other) {
     return kind_ == other.kind_;
   }
 
   Kind kind() const { return kind_; }
   bool IsNone() const { return kind_ == kNone; }
   bool IsTagged() const { return kind_ == kTagged; }
   bool IsInteger32() const { return kind_ == kInteger32; }
   bool IsDouble() const { return kind_ == kDouble; }
+  bool IsExternal() const { return kind_ == kExternal; }
   bool IsSpecialization() const {
     return kind_ == kInteger32 || kind_ == kDouble;
   }
   const char* Mnemonic() const;
 
  private:
   explicit Representation(Kind k) : kind_(k) { }
 
   Kind kind_;
 };
@@ skipping 205 matching lines @@
   // one input.  They are phi and binary add.  They always return NULL and
   // expect the caller to take care of things.
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited) {
     visited->Add(id());
     return NULL;
   }
 
   bool IsDefinedAfter(HBasicBlock* other) const;
 
   // Operands.
-  virtual int OperandCount() const { return 0; }
-  virtual HValue* OperandAt(int index) const {
-    UNREACHABLE();
-    return NULL;
-  }
+  virtual int OperandCount() = 0;
+  virtual HValue* OperandAt(int index) = 0;
   void SetOperandAt(int index, HValue* value);
 
-  int LookupOperandIndex(int occurrence_index, HValue* op) const;
-  bool UsesMultipleTimes(HValue* op) const;
+  int LookupOperandIndex(int occurrence_index, HValue* op);
+  bool UsesMultipleTimes(HValue* op);
 
   void ReplaceAndDelete(HValue* other);
   void ReplaceValue(HValue* other);
   void ReplaceAtUse(HValue* use, HValue* other);
   void ReplaceFirstAtUse(HValue* use, HValue* other, Representation r);
   bool HasNoUses() const { return uses_.is_empty(); }
   void ClearOperands();
   void Delete();
 
   int flags() const { return flags_; }
   void SetFlag(Flag f) { flags_ |= (1 << f); }
   void ClearFlag(Flag f) { flags_ &= ~(1 << f); }
   bool CheckFlag(Flag f) const { return (flags_ & (1 << f)) != 0; }
 
   void SetAllSideEffects() { flags_ |= AllSideEffects(); }
   void ClearAllSideEffects() { flags_ &= ~AllSideEffects(); }
   bool HasSideEffects() const { return (flags_ & AllSideEffects()) != 0; }
 
   Range* range() const { return range_; }
   bool HasRange() const { return range_ != NULL; }
   void AddNewRange(Range* r);
   void RemoveLastAddedRange();
   void ComputeInitialRange();
 
   // Representation helpers.
-  virtual Representation RequiredInputRepresentation(int index) const {
-    return Representation::None();
-  }
-  virtual Representation InferredRepresentation() const {
+  virtual Representation RequiredInputRepresentation(int index) const = 0;
+
+  virtual Representation InferredRepresentation() {
     return representation();
   }
 
   // This gives the instruction an opportunity to replace itself with an
   // instruction that does the same in some better way.  To replace an
   // instruction with a new one, first add the new instruction to the graph,
   // then return it.  Return NULL to have the instruction deleted.
   virtual HValue* Canonicalize() { return this; }
 
   // Declare virtual type testers.
 #define DECLARE_DO(type) virtual bool Is##type() const { return false; }
   HYDROGEN_ALL_INSTRUCTION_LIST(DECLARE_DO)
 #undef DECLARE_DO
 
-  bool Equals(HValue* other) const;
-  virtual intptr_t Hashcode() const;
+  bool Equals(HValue* other);
+  virtual intptr_t Hashcode();
 
   // Printing support.
-  virtual void PrintTo(StringStream* stream) const = 0;
+  virtual void PrintTo(StringStream* stream) = 0;
   void PrintNameTo(StringStream* stream);
   static void PrintTypeTo(HType type, StringStream* stream);
 
   virtual const char* Mnemonic() const = 0;
   virtual Opcode opcode() const = 0;
 
   // Updated the inferred type of this instruction and returns true if
   // it has changed.
   bool UpdateInferredType();
 
-  virtual HType CalculateInferredType() const;
-
-  // Helper for type conversions used by normal and phi instructions.
-  void InsertInputConversion(HInstruction* previous, int index, HType type);
+  virtual HType CalculateInferredType();
 
 #ifdef DEBUG
   virtual void Verify() = 0;
 #endif
 
  protected:
   // This function must be overridden for instructions with flag kUseGVN, to
   // compare the non-Operand parts of the instruction.
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     UNREACHABLE();
     return false;
   }
   virtual void RepresentationChanged(Representation to) { }
   virtual Range* InferRange();
   virtual void DeleteFromGraph() = 0;
-  virtual void InternalSetOperandAt(int index, HValue* value) { UNREACHABLE(); }
+  virtual void InternalSetOperandAt(int index, HValue* value) = 0;
   void clear_block() {
     ASSERT(block_ != NULL);
     block_ = NULL;
   }
 
   void set_representation(Representation r) {
     // Representation is set-once.
     ASSERT(representation_.IsNone() && !r.IsNone());
     representation_ = r;
   }
@@ skipping 21 matching lines @@
 
   DISALLOW_COPY_AND_ASSIGN(HValue);
 };
 
 
 class HInstruction: public HValue {
  public:
   HInstruction* next() const { return next_; }
   HInstruction* previous() const { return previous_; }
 
-  void PrintTo(StringStream* stream) const;
-  virtual void PrintDataTo(StringStream* stream) const {}
+  virtual void PrintTo(StringStream* stream);
+  virtual void PrintDataTo(StringStream* stream) { }
 
   bool IsLinked() const { return block() != NULL; }
   void Unlink();
   void InsertBefore(HInstruction* next);
   void InsertAfter(HInstruction* previous);
 
   int position() const { return position_; }
   bool has_position() const { return position_ != RelocInfo::kNoPosition; }
   void set_position(int position) { position_ = position; }
 
   virtual LInstruction* CompileToLithium(LChunkBuilder* builder) = 0;
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   // Returns whether this is some kind of deoptimizing check
   // instruction.
   virtual bool IsCheckInstruction() const { return false; }
 
+  virtual bool IsCall() { return false; }
+
   DECLARE_INSTRUCTION(Instruction)
 
  protected:
   HInstruction()
       : next_(NULL),
         previous_(NULL),
         position_(RelocInfo::kNoPosition) {
     SetFlag(kDependsOnOsrEntries);
   }
 
   virtual void DeleteFromGraph() { Unlink(); }
 
  private:
   void InitializeAsFirst(HBasicBlock* block) {
     ASSERT(!IsLinked());
     SetBlock(block);
   }
 
   HInstruction* next_;
   HInstruction* previous_;
   int position_;
 
   friend class HBasicBlock;
 };
 
 
-class HBlockEntry: public HInstruction {
- public:
-  DECLARE_CONCRETE_INSTRUCTION(BlockEntry, "block_entry")
-};
-
-
 class HControlInstruction: public HInstruction {
  public:
   HControlInstruction(HBasicBlock* first, HBasicBlock* second)
       : first_successor_(first), second_successor_(second) {
   }
 
   HBasicBlock* FirstSuccessor() const { return first_successor_; }
   HBasicBlock* SecondSuccessor() const { return second_successor_; }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_INSTRUCTION(ControlInstruction)
 
  private:
   HBasicBlock* first_successor_;
   HBasicBlock* second_successor_;
 };
 
 
-class HDeoptimize: public HControlInstruction {
+template<int NumElements>
+class HOperandContainer {
  public:
-  HDeoptimize() : HControlInstruction(NULL, NULL) { }
+  HOperandContainer() : elems_() { }
+
+  int length() { return NumElements; }
+  HValue*& operator[](int i) {
+    ASSERT(i < length());
+    return elems_[i];
+  }
+
+ private:
+  HValue* elems_[NumElements];
+};
+
+
+template<>
+class HOperandContainer<0> {
+ public:
+  int length() { return 0; }
+  HValue*& operator[](int i) {
+    UNREACHABLE();
+    static HValue* t = 0;
+    return t;
+  }
+};
+
+
+template<int V>
+class HTemplateInstruction : public HInstruction {
+ public:
+  int OperandCount() { return V; }
+  HValue* OperandAt(int i) { return inputs_[i]; }
+
+ protected:
+  void InternalSetOperandAt(int i, HValue* value) { inputs_[i] = value; }
+
+ private:
+  HOperandContainer<V> inputs_;
+};
+
+
+template<int V>
+class HTemplateControlInstruction : public HControlInstruction {
+ public:
+  HTemplateControlInstruction<V>(HBasicBlock* first, HBasicBlock* second)
+    : HControlInstruction(first, second) { }
+  int OperandCount() { return V; }
+  HValue* OperandAt(int i) { return inputs_[i]; }
+
+ protected:
+  void InternalSetOperandAt(int i, HValue* value) { inputs_[i] = value; }
+
+ private:
+  HOperandContainer<V> inputs_;
+};
+
+
+class HBlockEntry: public HTemplateInstruction<0> {
+ public:
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
+  DECLARE_CONCRETE_INSTRUCTION(BlockEntry, "block_entry")
+};
+
+
+class HDeoptimize: public HTemplateControlInstruction<0> {
+ public:
+  HDeoptimize() : HTemplateControlInstruction<0>(NULL, NULL) { }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(Deoptimize, "deoptimize")
 };
 
 
-class HGoto: public HControlInstruction {
+class HGoto: public HTemplateControlInstruction<0> {
  public:
   explicit HGoto(HBasicBlock* target)
-      : HControlInstruction(target, NULL), include_stack_check_(false) {
-  }
+      : HTemplateControlInstruction<0>(target, NULL),
+        include_stack_check_(false) { }
 
   void set_include_stack_check(bool include_stack_check) {
     include_stack_check_ = include_stack_check;
   }
   bool include_stack_check() const { return include_stack_check_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(Goto, "goto")
 
  private:
   bool include_stack_check_;
 };
 
 
-class HUnaryControlInstruction: public HControlInstruction {
+class HUnaryControlInstruction: public HTemplateControlInstruction<1> {
  public:
   explicit HUnaryControlInstruction(HValue* value,
                                     HBasicBlock* true_target,
                                     HBasicBlock* false_target)
-      : HControlInstruction(true_target, false_target) {
+      : HTemplateControlInstruction<1>(true_target, false_target) {
     SetOperandAt(0, value);
   }
 
-  virtual Representation RequiredInputRepresentation(int index) const {
-    return Representation::Tagged();
-  }
+  virtual void PrintDataTo(StringStream* stream);
 
-  virtual void PrintDataTo(StringStream* stream) const;
-
-  HValue* value() const { return OperandAt(0); }
-  virtual int OperandCount() const { return 1; }
-  virtual HValue* OperandAt(int index) const { return operands_[index]; }
+  HValue* value() { return OperandAt(0); }
 
   DECLARE_INSTRUCTION(UnaryControlInstruction)
-
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    operands_[index] = value;
-  }
-
- private:
-  HOperandVector<1> operands_;
 };
 
 
 class HTest: public HUnaryControlInstruction {
  public:
   HTest(HValue* value, HBasicBlock* true_target, HBasicBlock* false_target)
       : HUnaryControlInstruction(value, true_target, false_target) {
     ASSERT(true_target != NULL && false_target != NULL);
   }
 
@@ skipping 11 matching lines @@
               Handle<Map> map,
               HBasicBlock* true_target,
               HBasicBlock* false_target)
       : HUnaryControlInstruction(value, true_target, false_target),
         map_(map) {
     ASSERT(true_target != NULL);
     ASSERT(false_target != NULL);
     ASSERT(!map.is_null());
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   Handle<Map> map() const { return map_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(CompareMap, "compare_map")
 
  private:
   Handle<Map> map_;
 };
 
 
 class HReturn: public HUnaryControlInstruction {
  public:
   explicit HReturn(HValue* value)
       : HUnaryControlInstruction(value, NULL, NULL) {
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(Return, "return")
 };
 
 
-class HAbnormalExit: public HControlInstruction {
+class HAbnormalExit: public HTemplateControlInstruction<0> {
  public:
-  HAbnormalExit() : HControlInstruction(NULL, NULL) { }
+  HAbnormalExit() : HTemplateControlInstruction<0>(NULL, NULL) { }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(AbnormalExit, "abnormal_exit")
 };
 
 
-class HUnaryOperation: public HInstruction {
+class HUnaryOperation: public HTemplateInstruction<1> {
  public:
   explicit HUnaryOperation(HValue* value) {
     SetOperandAt(0, value);
   }
 
-  HValue* value() const { return OperandAt(0); }
-  virtual void PrintDataTo(StringStream* stream) const;
-  virtual int OperandCount() const { return 1; }
-  virtual HValue* OperandAt(int index) const { return operands_[index]; }
+  HValue* value() { return OperandAt(0); }
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_INSTRUCTION(UnaryOperation)
-
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    operands_[index] = value;
-  }
-
- private:
-  HOperandVector<1> operands_;
 };
 
 
 class HThrow: public HUnaryOperation {
  public:
   explicit HThrow(HValue* value) : HUnaryOperation(value) {
     SetAllSideEffects();
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
@@ skipping 29 matching lines @@
     return from_;
   }
 
   bool CanTruncateToInt32() const {
     for (int i = 0; i < uses()->length(); ++i) {
       if (!uses()->at(i)->CheckFlag(HValue::kTruncatingToInt32)) return false;
     }
     return true;
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(Change,
                                CanTruncateToInt32() ? "truncate" : "change")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     if (!other->IsChange()) return false;
     HChange* change = HChange::cast(other);
     return value() == change->value()
         && to().Equals(change->to())
         && CanTruncateToInt32() == change->CanTruncateToInt32();
   }
 
  private:
   Representation from_;
   Representation to_;
 };
 
 
 class HSimulate: public HInstruction {
  public:
   HSimulate(int ast_id, int pop_count, int environment_length)
       : ast_id_(ast_id),
         pop_count_(pop_count),
         environment_length_(environment_length),
         values_(2),
         assigned_indexes_(2) {}
   virtual ~HSimulate() {}
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   bool HasAstId() const { return ast_id_ != AstNode::kNoNumber; }
   int ast_id() const { return ast_id_; }
   void set_ast_id(int id) {
     ASSERT(!HasAstId());
     ast_id_ = id;
   }
 
   int environment_length() const { return environment_length_; }
   int pop_count() const { return pop_count_; }
   const ZoneList<HValue*>* values() const { return &values_; }
   int GetAssignedIndexAt(int index) const {
     ASSERT(HasAssignedIndexAt(index));
     return assigned_indexes_[index];
   }
   bool HasAssignedIndexAt(int index) const {
     return assigned_indexes_[index] != kNoIndex;
   }
   void AddAssignedValue(int index, HValue* value) {
     AddValue(index, value);
   }
   void AddPushedValue(HValue* value) {
     AddValue(kNoIndex, value);
   }
-  virtual int OperandCount() const { return values_.length(); }
-  virtual HValue* OperandAt(int index) const { return values_[index]; }
+  virtual int OperandCount() { return values_.length(); }
+  virtual HValue* OperandAt(int index) { return values_[index]; }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(Simulate, "simulate")
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
  protected:
   virtual void InternalSetOperandAt(int index, HValue* value) {
     values_[index] = value;
@@ skipping 10 matching lines @@
     SetOperandAt(values_.length() - 1, value);
   }
   int ast_id_;
   int pop_count_;
   int environment_length_;
   ZoneList<HValue*> values_;
   ZoneList<int> assigned_indexes_;
 };
 
 
-class HStackCheck: public HInstruction {
+class HStackCheck: public HTemplateInstruction<0> {
  public:
   HStackCheck() { }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(StackCheck, "stack_check")
 };
 
 
-class HEnterInlined: public HInstruction {
+class HEnterInlined: public HTemplateInstruction<0> {
  public:
   HEnterInlined(Handle<JSFunction> closure, FunctionLiteral* function)
       : closure_(closure), function_(function) {
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   Handle<JSFunction> closure() const { return closure_; }
   FunctionLiteral* function() const { return function_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(EnterInlined, "enter_inlined")
 
  private:
   Handle<JSFunction> closure_;
   FunctionLiteral* function_;
 };
 
 
-class HLeaveInlined: public HInstruction {
+class HLeaveInlined: public HTemplateInstruction<0> {
  public:
   HLeaveInlined() {}
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(LeaveInlined, "leave_inlined")
 };
 
 
 class HPushArgument: public HUnaryOperation {
  public:
-  explicit HPushArgument(HValue* value)
-      : HUnaryOperation(value), argument_index_(-1) {
+  explicit HPushArgument(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
-  HValue* argument() const { return OperandAt(0); }
-  int argument_index() const { return argument_index_; }
-  void set_argument_index(int index) {
-    ASSERT(argument_index_ == -1 || index == argument_index_);
-    argument_index_ = index;
-  }
+  HValue* argument() { return OperandAt(0); }
 
   DECLARE_CONCRETE_INSTRUCTION(PushArgument, "push_argument")
-
- private:
-  int argument_index_;
 };
 
 
-class HContext: public HInstruction {
+class HContext: public HTemplateInstruction<0> {
  public:
   HContext() {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(Context, "context");
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HOuterContext: public HUnaryOperation {
  public:
   explicit HOuterContext(HValue* inner) : HUnaryOperation(inner) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   DECLARE_CONCRETE_INSTRUCTION(OuterContext, "outer_context");
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HGlobalObject: public HUnaryOperation {
  public:
   explicit HGlobalObject(HValue* context) : HUnaryOperation(context) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   DECLARE_CONCRETE_INSTRUCTION(GlobalObject, "global_object")
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HGlobalReceiver: public HUnaryOperation {
  public:
   explicit HGlobalReceiver(HValue* global_object)
       : HUnaryOperation(global_object) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   DECLARE_CONCRETE_INSTRUCTION(GlobalReceiver, "global_receiver")
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HCall: public HInstruction {
+template <int V>
+class HCall: public HTemplateInstruction<V> {
  public:
-  // Construct a call with uninitialized arguments. The argument count
-  // includes the receiver.
-  explicit HCall(int count);
-
-  virtual HType CalculateInferredType() const { return HType::Tagged(); }
-
-  // TODO(3190496): This needs a cleanup. We don't want the arguments
-  // be operands of the call instruction. This results in bad code quality.
-  virtual int argument_count() const { return arguments_.length(); }
-  virtual int OperandCount() const { return argument_count(); }
-  virtual HValue* OperandAt(int index) const { return arguments_[index]; }
-  virtual HPushArgument* PushArgumentAt(int index) const {
-    return HPushArgument::cast(OperandAt(index));
-  }
-  virtual HValue* ArgumentAt(int index) const {
-    return PushArgumentAt(index)->argument();
-  }
-  virtual void SetArgumentAt(int index, HPushArgument* push_argument);
-
-  virtual void PrintDataTo(StringStream* stream) const;
-
-  DECLARE_INSTRUCTION(Call)
-
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    arguments_[index] = value;
+  // The argument count includes the receiver.
+  explicit HCall<V>(int argument_count) : argument_count_(argument_count) {
+    this->set_representation(Representation::Tagged());
+    this->SetAllSideEffects();
   }
 
+  virtual HType CalculateInferredType() { return HType::Tagged(); }
+
+  virtual int argument_count() const { return argument_count_; }
+
+  virtual bool IsCall() { return true; }
+
+ private:
   int argument_count_;
-  Vector<HValue*> arguments_;
 };
 
 
-class HCallConstantFunction: public HCall {
+class HUnaryCall: public HCall<1> {
+ public:
+  HUnaryCall(HValue* value, int argument_count)
+      : HCall<1>(argument_count) {
+    SetOperandAt(0, value);
+  }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
+  virtual void PrintDataTo(StringStream* stream);
+
+  HValue* value() { return OperandAt(0); }
+
+  DECLARE_INSTRUCTION(UnaryCall)
+};
+
+
+class HBinaryCall: public HCall<2> {
+ public:
+  HBinaryCall(HValue* first, HValue* second, int argument_count)
+      : HCall<2>(argument_count) {
+    SetOperandAt(0, first);
+    SetOperandAt(1, second);
+  }
+
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
+  HValue* first() { return OperandAt(0); }
+  HValue* second() { return OperandAt(1); }
+
+  DECLARE_INSTRUCTION(BinaryCall)
+};
+
+
+class HCallConstantFunction: public HCall<0> {
  public:
   HCallConstantFunction(Handle<JSFunction> function, int argument_count)
-      : HCall(argument_count), function_(function) { }
+      : HCall<0>(argument_count), function_(function) { }
 
   Handle<JSFunction> function() const { return function_; }
+
   bool IsApplyFunction() const {
     return function_->code() ==
         Isolate::Current()->builtins()->builtin(Builtins::FunctionApply);
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(CallConstantFunction, "call_constant_function")
 
  private:
   Handle<JSFunction> function_;
 };
 
 
-class HCallKeyed: public HCall {
+class HCallKeyed: public HBinaryCall {
  public:
-  HCallKeyed(HValue* key, int argument_count)
-      : HCall(argument_count + 1) {
-    SetOperandAt(0, key);
+  HCallKeyed(HValue* context, HValue* key, int argument_count)
+      : HBinaryCall(context, key, argument_count) {
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  // TODO(3190496): This is a hack to get an additional operand that
-  // is not an argument to work with the current setup. This _needs_ a cleanup.
-  // (see HCall)
-  virtual void PrintDataTo(StringStream* stream) const;
-  HValue* key() const { return OperandAt(0); }
-  virtual int argument_count() const { return arguments_.length() - 1; }
-  virtual int OperandCount() const { return arguments_.length(); }
-  virtual HValue* OperandAt(int index) const { return arguments_[index]; }
-  virtual HPushArgument* PushArgumentAt(int index) const {
-    return HPushArgument::cast(OperandAt(index + 1));
-  }
-  virtual void SetArgumentAt(int index, HPushArgument* push_argument) {
-    HCall::SetArgumentAt(index + 1, push_argument);
-  }
+  HValue* context() { return first(); }
+  HValue* key() { return second(); }
 
   DECLARE_CONCRETE_INSTRUCTION(CallKeyed, "call_keyed")
 };
 
 
-class HCallNamed: public HCall {
+class HCallNamed: public HUnaryCall {
  public:
-  HCallNamed(Handle<String> name, int argument_count)
-      : HCall(argument_count), name_(name) { }
-  virtual void PrintDataTo(StringStream* stream) const;
+  HCallNamed(HValue* context, Handle<String> name, int argument_count)
+      : HUnaryCall(context, argument_count), name_(name) {
+  }
 
+  virtual void PrintDataTo(StringStream* stream);
+
+  HValue* context() { return value(); }
   Handle<String> name() const { return name_; }
 
   DECLARE_CONCRETE_INSTRUCTION(CallNamed, "call_named")
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
  private:
   Handle<String> name_;
 };
 
 
-class HCallFunction: public HCall {
+class HCallFunction: public HUnaryCall {
  public:
-  explicit HCallFunction(int argument_count) : HCall(argument_count) { }
+  HCallFunction(HValue* context, int argument_count)
+      : HUnaryCall(context, argument_count) {
+  }
+
+  HValue* context() { return value(); }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(CallFunction, "call_function")
 };
 
 
-class HCallGlobal: public HCall {
+class HCallGlobal: public HUnaryCall {
  public:
-  HCallGlobal(Handle<String> name, int argument_count)
-      : HCall(argument_count), name_(name) { }
+  HCallGlobal(HValue* context, Handle<String> name, int argument_count)
+      : HUnaryCall(context, argument_count), name_(name) {
+  }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
+  HValue* context() { return value(); }
   Handle<String> name() const { return name_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(CallGlobal, "call_global")
 
  private:
   Handle<String> name_;
 };
 
 
-class HCallKnownGlobal: public HCall {
+class HCallKnownGlobal: public HCall<0> {
  public:
-  HCallKnownGlobal(Handle<JSFunction> target,
-                   int argument_count)
-      : HCall(argument_count), target_(target) { }
+  HCallKnownGlobal(Handle<JSFunction> target, int argument_count)
+      : HCall<0>(argument_count), target_(target) { }
+
+  virtual void PrintDataTo(StringStream* stream);
 
   Handle<JSFunction> target() const { return target_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(CallKnownGlobal, "call_known_global")
 
  private:
   Handle<JSFunction> target_;
 };
 
 
-class HCallNew: public HCall {
+class HCallNew: public HBinaryCall {
  public:
-  explicit HCallNew(int argument_count) : HCall(argument_count) { }
+  HCallNew(HValue* context, HValue* constructor, int argument_count)
+      : HBinaryCall(context, constructor, argument_count) {
+  }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  HValue* constructor() const { return ArgumentAt(0); }
+  HValue* context() { return first(); }
+  HValue* constructor() { return second(); }
 
   DECLARE_CONCRETE_INSTRUCTION(CallNew, "call_new")
 };
 
 
-class HCallRuntime: public HCall {
+class HCallRuntime: public HCall<0> {
  public:
   HCallRuntime(Handle<String> name,
                const Runtime::Function* c_function,
                int argument_count)
-      : HCall(argument_count), c_function_(c_function), name_(name) { }
-  virtual void PrintDataTo(StringStream* stream) const;
+      : HCall<0>(argument_count), c_function_(c_function), name_(name) { }
+  virtual void PrintDataTo(StringStream* stream);
 
   const Runtime::Function* function() const { return c_function_; }
   Handle<String> name() const { return name_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(CallRuntime, "call_runtime")
 
  private:
   const Runtime::Function* c_function_;
   Handle<String> name_;
 };
 
 
 class HJSArrayLength: public HUnaryOperation {
  public:
   explicit HJSArrayLength(HValue* value) : HUnaryOperation(value) {
     // The length of an array is stored as a tagged value in the array
     // object. It is guaranteed to be 32 bit integer, but it can be
     // represented as either a smi or heap number.
     set_representation(Representation::Tagged());
     SetFlag(kDependsOnArrayLengths);
     SetFlag(kUseGVN);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(JSArrayLength, "js_array_length")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HFixedArrayLength: public HUnaryOperation {
  public:
   explicit HFixedArrayLength(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
     SetFlag(kDependsOnArrayLengths);
     SetFlag(kUseGVN);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(FixedArrayLength, "fixed_array_length")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
+};
+
+
+class HPixelArrayLength: public HUnaryOperation {
+ public:
+  explicit HPixelArrayLength(HValue* value) : HUnaryOperation(value) {
+    set_representation(Representation::Integer32());
+    // The result of this instruction is idempotent as long as its inputs don't
+    // change.  The length of a pixel array cannot change once set, so it's not
+    // necessary to introduce a kDependsOnArrayLengths or any other dependency.
+    SetFlag(kUseGVN);
+  }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
+  DECLARE_CONCRETE_INSTRUCTION(PixelArrayLength, "pixel_array_length")
+
+ protected:
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HBitNot: public HUnaryOperation {
  public:
   explicit HBitNot(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Integer32());
     SetFlag(kUseGVN);
     SetFlag(kTruncatingToInt32);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Integer32();
   }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(BitNot, "bit_not")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HUnaryMathOperation: public HUnaryOperation {
  public:
   HUnaryMathOperation(HValue* value, BuiltinFunctionId op)
       : HUnaryOperation(value), op_(op) {
     switch (op) {
       case kMathFloor:
       case kMathRound:
@@ skipping 10 matching lines @@
       case kMathSin:
       case kMathCos:
         set_representation(Representation::Double());
         break;
       default:
         UNREACHABLE();
     }
     SetFlag(kUseGVN);
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited);
 
   virtual Representation RequiredInputRepresentation(int index) const {
     switch (op_) {
       case kMathFloor:
       case kMathRound:
       case kMathCeil:
       case kMathSqrt:
       case kMathPowHalf:
       case kMathLog:
       case kMathSin:
       case kMathCos:
         return Representation::Double();
-        break;
       case kMathAbs:
         return representation();
-        break;
       default:
+        UNREACHABLE();
         return Representation::None();
     }
   }
 
   virtual HValue* Canonicalize() {
     // If the input is integer32 then we replace the floor instruction
     // with its inputs.  This happens before the representation changes are
     // introduced.
     if (op() == kMathFloor) {
       if (value()->representation().IsInteger32()) return value();
     }
     return this;
   }
 
   BuiltinFunctionId op() const { return op_; }
   const char* OpName() const;
 
   DECLARE_CONCRETE_INSTRUCTION(UnaryMathOperation, "unary_math_operation")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HUnaryMathOperation* b = HUnaryMathOperation::cast(other);
     return op_ == b->op();
   }
 
  private:
   BuiltinFunctionId op_;
 };
 
 
 class HLoadElements: public HUnaryOperation {
  public:
   explicit HLoadElements(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     SetFlag(kDependsOnMaps);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(LoadElements, "load-elements")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
+};
+
+
+class HLoadPixelArrayExternalPointer: public HUnaryOperation {
+ public:
+  explicit HLoadPixelArrayExternalPointer(HValue* value)
+      : HUnaryOperation(value) {
+    set_representation(Representation::External());
+    // The result of this instruction is idempotent as long as its inputs don't
+    // change.  The external array of a pixel array elements object cannot
+    // change once set, so it's no necessary to introduce any additional
+    // dependencies on top of the inputs.
+    SetFlag(kUseGVN);
+  }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
+  DECLARE_CONCRETE_INSTRUCTION(LoadPixelArrayExternalPointer,
+                               "load-pixel-array-external-pointer")
+
+ protected:
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HCheckMap: public HUnaryOperation {
  public:
   HCheckMap(HValue* value, Handle<Map> map)
       : HUnaryOperation(value), map_(map) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     SetFlag(kDependsOnMaps);
   }
 
   virtual bool IsCheckInstruction() const { return true; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual void PrintDataTo(StringStream* stream) const;
-  virtual HType CalculateInferredType() const;
+  virtual void PrintDataTo(StringStream* stream);
+  virtual HType CalculateInferredType();
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   Handle<Map> map() const { return map_; }
 
   DECLARE_CONCRETE_INSTRUCTION(CheckMap, "check_map")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HCheckMap* b = HCheckMap::cast(other);
     return map_.is_identical_to(b->map());
   }
 
  private:
   Handle<Map> map_;
 };
 
 
 class HCheckFunction: public HUnaryOperation {
  public:
   HCheckFunction(HValue* value, Handle<JSFunction> function)
       : HUnaryOperation(value), target_(function) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   virtual bool IsCheckInstruction() const { return true; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual void PrintDataTo(StringStream* stream) const;
-  virtual HType CalculateInferredType() const;
+  virtual void PrintDataTo(StringStream* stream);
+  virtual HType CalculateInferredType();
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   Handle<JSFunction> target() const { return target_; }
 
   DECLARE_CONCRETE_INSTRUCTION(CheckFunction, "check_function")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HCheckFunction* b = HCheckFunction::cast(other);
     return target_.is_identical_to(b->target());
   }
 
  private:
   Handle<JSFunction> target_;
 };
 
 
 class HCheckInstanceType: public HUnaryOperation {
@@ skipping 27 matching lines @@
 
   InstanceType first() const { return first_; }
   InstanceType last() const { return last_; }
 
   DECLARE_CONCRETE_INSTRUCTION(CheckInstanceType, "check_instance_type")
 
  protected:
   // TODO(ager): It could be nice to allow the ommision of instance
   // type checks if we have already performed an instance type check
   // with a larger range.
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HCheckInstanceType* b = HCheckInstanceType::cast(other);
     return (first_ == b->first()) && (last_ == b->last());
   }
 
  private:
   InstanceType first_;
   InstanceType last_;
 };
 
 
 class HCheckNonSmi: public HUnaryOperation {
  public:
   explicit HCheckNonSmi(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   virtual bool IsCheckInstruction() const { return true; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   DECLARE_CONCRETE_INSTRUCTION(CheckNonSmi, "check_non_smi")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HCheckPrototypeMaps: public HInstruction {
+class HCheckPrototypeMaps: public HTemplateInstruction<0> {
  public:
   HCheckPrototypeMaps(Handle<JSObject> prototype, Handle<JSObject> holder)
       : prototype_(prototype), holder_(holder) {
     SetFlag(kUseGVN);
     SetFlag(kDependsOnMaps);
   }
 
   virtual bool IsCheckInstruction() const { return true; }
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   Handle<JSObject> prototype() const { return prototype_; }
   Handle<JSObject> holder() const { return holder_; }
 
   DECLARE_CONCRETE_INSTRUCTION(CheckPrototypeMaps, "check_prototype_maps")
 
-  virtual intptr_t Hashcode() const {
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
+  virtual intptr_t Hashcode() {
     ASSERT(!HEAP->IsAllocationAllowed());
     intptr_t hash = reinterpret_cast<intptr_t>(*prototype());
     hash = 17 * hash + reinterpret_cast<intptr_t>(*holder());
     return hash;
   }
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HCheckPrototypeMaps* b = HCheckPrototypeMaps::cast(other);
     return prototype_.is_identical_to(b->prototype()) &&
         holder_.is_identical_to(b->holder());
   }
 
  private:
   Handle<JSObject> prototype_;
   Handle<JSObject> holder_;
 };
 
 
 class HCheckSmi: public HUnaryOperation {
  public:
   explicit HCheckSmi(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   virtual bool IsCheckInstruction() const { return true; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   DECLARE_CONCRETE_INSTRUCTION(CheckSmi, "check_smi")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HPhi: public HValue {
  public:
   explicit HPhi(int merged_index)
       : inputs_(2),
         merged_index_(merged_index),
         phi_id_(-1) {
     for (int i = 0; i < Representation::kNumRepresentations; i++) {
       non_phi_uses_[i] = 0;
       indirect_uses_[i] = 0;
     }
     ASSERT(merged_index >= 0);
     set_representation(Representation::Tagged());
     SetFlag(kFlexibleRepresentation);
   }
 
-  virtual Representation InferredRepresentation() const {
+  virtual Representation InferredRepresentation() {
     bool double_occurred = false;
     bool int32_occurred = false;
     for (int i = 0; i < OperandCount(); ++i) {
       HValue* value = OperandAt(i);
       if (value->representation().IsDouble()) double_occurred = true;
       if (value->representation().IsInteger32()) int32_occurred = true;
       if (value->representation().IsTagged()) return Representation::Tagged();
     }
 
     if (double_occurred) return Representation::Double();
     if (int32_occurred) return Representation::Integer32();
     return Representation::None();
   }
 
   virtual Range* InferRange();
   virtual Representation RequiredInputRepresentation(int index) const {
     return representation();
   }
-  virtual HType CalculateInferredType() const;
-  virtual int OperandCount() const { return inputs_.length(); }
-  virtual HValue* OperandAt(int index) const { return inputs_[index]; }
-  HValue* GetRedundantReplacement() const;
+  virtual HType CalculateInferredType();
+  virtual int OperandCount() { return inputs_.length(); }
+  virtual HValue* OperandAt(int index) { return inputs_[index]; }
+  HValue* GetRedundantReplacement();
   void AddInput(HValue* value);
 
   bool IsReceiver() { return merged_index_ == 0; }
 
   int merged_index() const { return merged_index_; }
 
   virtual const char* Mnemonic() const { return "phi"; }
 
-  virtual void PrintTo(StringStream* stream) const;
+  virtual void PrintTo(StringStream* stream);
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
   DECLARE_INSTRUCTION(Phi)
 
   void InitRealUses(int id);
   void AddNonPhiUsesFrom(HPhi* other);
   void AddIndirectUsesTo(int* use_count);
@@ skipping 27 matching lines @@
  private:
   ZoneList<HValue*> inputs_;
   int merged_index_;
 
   int non_phi_uses_[Representation::kNumRepresentations];
   int indirect_uses_[Representation::kNumRepresentations];
   int phi_id_;
 };
 
 
-class HArgumentsObject: public HInstruction {
+class HArgumentsObject: public HTemplateInstruction<0> {
  public:
   HArgumentsObject() {
     set_representation(Representation::Tagged());
     SetFlag(kIsArguments);
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(ArgumentsObject, "arguments-object")
 };
 
 
-class HConstant: public HInstruction {
+class HConstant: public HTemplateInstruction<0> {
  public:
   HConstant(Handle<Object> handle, Representation r);
 
   Handle<Object> handle() const { return handle_; }
 
   bool InOldSpace() const { return !HEAP->InNewSpace(*handle_); }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   virtual bool EmitAtUses() const { return !representation().IsDouble(); }
-  virtual void PrintDataTo(StringStream* stream) const;
-  virtual HType CalculateInferredType() const;
+  virtual void PrintDataTo(StringStream* stream);
+  virtual HType CalculateInferredType();
   bool IsInteger() const { return handle_->IsSmi(); }
   HConstant* CopyToRepresentation(Representation r) const;
   HConstant* CopyToTruncatedInt32() const;
   bool HasInteger32Value() const { return has_int32_value_; }
   int32_t Integer32Value() const {
     ASSERT(HasInteger32Value());
     return int32_value_;
   }
   bool HasDoubleValue() const { return has_double_value_; }
   double DoubleValue() const {
     ASSERT(HasDoubleValue());
     return double_value_;
   }
   bool HasStringValue() const { return handle_->IsString(); }
 
-  virtual intptr_t Hashcode() const {
+  virtual intptr_t Hashcode() {
     ASSERT(!HEAP->allow_allocation(false));
     return reinterpret_cast<intptr_t>(*handle());
   }
 
 #ifdef DEBUG
   virtual void Verify() { }
 #endif
 
   DECLARE_CONCRETE_INSTRUCTION(Constant, "constant")
 
  protected:
   virtual Range* InferRange();
 
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HConstant* other_constant = HConstant::cast(other);
     return handle().is_identical_to(other_constant->handle());
   }
 
  private:
   Handle<Object> handle_;
   HType constant_type_;
 
   // The following two values represent the int32 and the double value of the
   // given constant if there is a lossless conversion between the constant
   // and the specific representation.
   bool has_int32_value_;
   int32_t int32_value_;
   bool has_double_value_;
   double double_value_;
 };
 
 
-class HBinaryOperation: public HInstruction {
+class HBinaryOperation: public HTemplateInstruction<2> {
  public:
   HBinaryOperation(HValue* left, HValue* right) {
     ASSERT(left != NULL && right != NULL);
     SetOperandAt(0, left);
     SetOperandAt(1, right);
   }
 
-  HValue* left() const { return OperandAt(0); }
-  HValue* right() const { return OperandAt(1); }
+  HValue* left() { return OperandAt(0); }
+  HValue* right() { return OperandAt(1); }
 
   // TODO(kasperl): Move these helpers to the IA-32 Lithium
   // instruction sequence builder.
-  HValue* LeastConstantOperand() const {
+  HValue* LeastConstantOperand() {
     if (IsCommutative() && left()->IsConstant()) return right();
     return left();
   }
-  HValue* MostConstantOperand() const {
+  HValue* MostConstantOperand() {
     if (IsCommutative() && left()->IsConstant()) return left();
     return right();
   }
 
   virtual bool IsCommutative() const { return false; }
 
-  virtual void PrintDataTo(StringStream* stream) const;
-  virtual int OperandCount() const { return operands_.length(); }
-  virtual HValue* OperandAt(int index) const { return operands_[index]; }
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_INSTRUCTION(BinaryOperation)
-
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    operands_[index] = value;
-  }
-
- private:
-  HOperandVector<2> operands_;
 };
 
 
-class HApplyArguments: public HInstruction {
+class HApplyArguments: public HTemplateInstruction<4> {
  public:
   HApplyArguments(HValue* function,
                   HValue* receiver,
                   HValue* length,
                   HValue* elements) {
     set_representation(Representation::Tagged());
     SetOperandAt(0, function);
     SetOperandAt(1, receiver);
     SetOperandAt(2, length);
     SetOperandAt(3, elements);
     SetAllSideEffects();
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     // The length is untagged, all other inputs are tagged.
     return (index == 2)
         ? Representation::Integer32()
         : Representation::Tagged();
   }
 
-  HValue* function() const { return OperandAt(0); }
-  HValue* receiver() const { return OperandAt(1); }
-  HValue* length() const { return OperandAt(2); }
-  HValue* elements() const { return OperandAt(3); }
-
-  virtual int OperandCount() const { return operands_.length(); }
-  virtual HValue* OperandAt(int index) const { return operands_[index]; }
+  HValue* function() { return OperandAt(0); }
+  HValue* receiver() { return OperandAt(1); }
+  HValue* length() { return OperandAt(2); }
+  HValue* elements() { return OperandAt(3); }
 
   DECLARE_CONCRETE_INSTRUCTION(ApplyArguments, "apply_arguments")
-
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    operands_[index] = value;
-  }
-
- private:
-  HOperandVector<4> operands_;
 };
 
 
-class HArgumentsElements: public HInstruction {
+class HArgumentsElements: public HTemplateInstruction<0> {
  public:
   HArgumentsElements() {
     // The value produced by this instruction is a pointer into the stack
     // that looks as if it was a smi because of alignment.
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   DECLARE_CONCRETE_INSTRUCTION(ArgumentsElements, "arguments_elements")
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HArgumentsLength: public HUnaryOperation {
  public:
   explicit HArgumentsLength(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Integer32());
     SetFlag(kUseGVN);
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(ArgumentsLength, "arguments_length")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HAccessArgumentsAt: public HInstruction {
+class HAccessArgumentsAt: public HTemplateInstruction<3> {
  public:
   HAccessArgumentsAt(HValue* arguments, HValue* length, HValue* index) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     SetOperandAt(0, arguments);
     SetOperandAt(1, length);
     SetOperandAt(2, index);
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   virtual Representation RequiredInputRepresentation(int index) const {
     // The arguments elements is considered tagged.
     return index == 0
         ? Representation::Tagged()
         : Representation::Integer32();
   }
 
-  HValue* arguments() const { return operands_[0]; }
-  HValue* length() const { return operands_[1]; }
-  HValue* index() const { return operands_[2]; }
-
-  virtual int OperandCount() const { return operands_.length(); }
-  virtual HValue* OperandAt(int index) const { return operands_[index]; }
+  HValue* arguments() { return OperandAt(0); }
+  HValue* length() { return OperandAt(1); }
+  HValue* index() { return OperandAt(2); }
 
   DECLARE_CONCRETE_INSTRUCTION(AccessArgumentsAt, "access_arguments_at")
 
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    operands_[index] = value;
-  }
-
-  virtual bool DataEquals(HValue* other) const { return true; }
-
- private:
-  HOperandVector<3> operands_;
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HBoundsCheck: public HBinaryOperation {
  public:
   HBoundsCheck(HValue* index, HValue* length)
       : HBinaryOperation(index, length) {
     SetFlag(kUseGVN);
   }
 
   virtual bool IsCheckInstruction() const { return true; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Integer32();
   }
 
 #ifdef DEBUG
   virtual void Verify();
 #endif
 
-  HValue* index() const { return left(); }
-  HValue* length() const { return right(); }
+  HValue* index() { return left(); }
+  HValue* length() { return right(); }
 
   DECLARE_CONCRETE_INSTRUCTION(BoundsCheck, "bounds_check")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HBitwiseBinaryOperation: public HBinaryOperation {
  public:
   HBitwiseBinaryOperation(HValue* left, HValue* right)
       : HBinaryOperation(left, right) {
     set_representation(Representation::Tagged());
     SetFlag(kFlexibleRepresentation);
     SetAllSideEffects();
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return representation();
   }
 
   virtual void RepresentationChanged(Representation to) {
     if (!to.IsTagged()) {
       ASSERT(to.IsInteger32());
       ClearAllSideEffects();
       SetFlag(kTruncatingToInt32);
       SetFlag(kUseGVN);
     }
   }
 
-  HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_INSTRUCTION(BitwiseBinaryOperation)
 };
 
 
 class HArithmeticBinaryOperation: public HBinaryOperation {
  public:
   HArithmeticBinaryOperation(HValue* left, HValue* right)
       : HBinaryOperation(left, right) {
     set_representation(Representation::Tagged());
     SetFlag(kFlexibleRepresentation);
     SetAllSideEffects();
   }
 
   virtual void RepresentationChanged(Representation to) {
     if (!to.IsTagged()) {
       ClearAllSideEffects();
       SetFlag(kUseGVN);
     }
   }
 
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
   virtual Representation RequiredInputRepresentation(int index) const {
     return representation();
   }
-  virtual Representation InferredRepresentation() const {
+  virtual Representation InferredRepresentation() {
     if (left()->representation().Equals(right()->representation())) {
       return left()->representation();
     }
     return HValue::InferredRepresentation();
   }
 
   DECLARE_INSTRUCTION(ArithmeticBinaryOperation)
 };
 
 
 class HCompare: public HBinaryOperation {
  public:
   HCompare(HValue* left, HValue* right, Token::Value token)
       : HBinaryOperation(left, right), token_(token) {
     ASSERT(Token::IsCompareOp(token));
     set_representation(Representation::Tagged());
     SetAllSideEffects();
   }
 
   void SetInputRepresentation(Representation r);
-  virtual bool EmitAtUses() const { return uses()->length() <= 1; }
+
+  virtual bool EmitAtUses() const {
+    return !HasSideEffects() && (uses()->length() <= 1);
+  }
+
   virtual Representation RequiredInputRepresentation(int index) const {
     return input_representation_;
   }
   Representation GetInputRepresentation() const {
     return input_representation_;
   }
   Token::Value token() const { return token_; }
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
-  virtual intptr_t Hashcode() const {
+  virtual intptr_t Hashcode() {
     return HValue::Hashcode() * 7 + token_;
   }
 
   DECLARE_CONCRETE_INSTRUCTION(Compare, "compare")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HCompare* comp = HCompare::cast(other);
     return token_ == comp->token();
   }
 
  private:
   Representation input_representation_;
   Token::Value token_;
 };
 
 
 class HCompareJSObjectEq: public HBinaryOperation {
  public:
   HCompareJSObjectEq(HValue* left, HValue* right)
       : HBinaryOperation(left, right) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
-  virtual bool EmitAtUses() const { return uses()->length() <= 1; }
+  virtual bool EmitAtUses() const {
+    return !HasSideEffects() && (uses()->length() <= 1);
+  }
+
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(CompareJSObjectEq, "compare-js-object-eq")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HUnaryPredicate: public HUnaryOperation {
  public:
   explicit HUnaryPredicate(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
-  virtual bool EmitAtUses() const { return uses()->length() <= 1; }
+
+  virtual bool EmitAtUses() const {
+    return !HasSideEffects() && (uses()->length() <= 1);
+  }
+
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 };
 
 
 class HIsNull: public HUnaryPredicate {
  public:
   HIsNull(HValue* value, bool is_strict)
       : HUnaryPredicate(value), is_strict_(is_strict) { }
 
   bool is_strict() const { return is_strict_; }
 
   DECLARE_CONCRETE_INSTRUCTION(IsNull, "is_null")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HIsNull* b = HIsNull::cast(other);
     return is_strict_ == b->is_strict();
   }
 
  private:
   bool is_strict_;
 };
 
 
 class HIsObject: public HUnaryPredicate {
  public:
   explicit HIsObject(HValue* value) : HUnaryPredicate(value) { }
 
   DECLARE_CONCRETE_INSTRUCTION(IsObject, "is_object")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HIsSmi: public HUnaryPredicate {
  public:
   explicit HIsSmi(HValue* value) : HUnaryPredicate(value) { }
 
   DECLARE_CONCRETE_INSTRUCTION(IsSmi, "is_smi")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HIsConstructCall: public HInstruction {
+class HIsConstructCall: public HTemplateInstruction<0> {
  public:
   HIsConstructCall() {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
-  virtual bool EmitAtUses() const { return uses()->length() <= 1; }
+  virtual bool EmitAtUses() const {
+    return !HasSideEffects() && (uses()->length() <= 1);
+  }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(IsConstructCall, "is_construct_call")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HHasInstanceType: public HUnaryPredicate {
  public:
   HHasInstanceType(HValue* value, InstanceType type)
       : HUnaryPredicate(value), from_(type), to_(type) { }
   HHasInstanceType(HValue* value, InstanceType from, InstanceType to)
       : HUnaryPredicate(value), from_(from), to_(to) {
     ASSERT(to == LAST_TYPE);  // Others not implemented yet in backend.
   }
 
   InstanceType from() { return from_; }
   InstanceType to() { return to_; }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(HasInstanceType, "has_instance_type")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HHasInstanceType* b = HHasInstanceType::cast(other);
     return (from_ == b->from()) && (to_ == b->to());
   }
 
  private:
   InstanceType from_;
   InstanceType to_;  // Inclusive range, not all combinations work.
 };
 
 
 class HHasCachedArrayIndex: public HUnaryPredicate {
  public:
   explicit HHasCachedArrayIndex(HValue* value) : HUnaryPredicate(value) { }
 
   DECLARE_CONCRETE_INSTRUCTION(HasCachedArrayIndex, "has_cached_array_index")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
+};
+
+
+class HGetCachedArrayIndex: public HUnaryPredicate {
+ public:
+  explicit HGetCachedArrayIndex(HValue* value) : HUnaryPredicate(value) { }
+
+  DECLARE_CONCRETE_INSTRUCTION(GetCachedArrayIndex, "get_cached_array_index")
+
+ protected:
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HClassOfTest: public HUnaryPredicate {
  public:
   HClassOfTest(HValue* value, Handle<String> class_name)
       : HUnaryPredicate(value), class_name_(class_name) { }
 
   DECLARE_CONCRETE_INSTRUCTION(ClassOfTest, "class_of_test")
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   Handle<String> class_name() const { return class_name_; }
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HClassOfTest* b = HClassOfTest::cast(other);
     return class_name_.is_identical_to(b->class_name_);
   }
 
  private:
   Handle<String> class_name_;
 };
 
 
 class HTypeofIs: public HUnaryPredicate {
  public:
   HTypeofIs(HValue* value, Handle<String> type_literal)
       : HUnaryPredicate(value), type_literal_(type_literal) { }
 
   Handle<String> type_literal() { return type_literal_; }
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(TypeofIs, "typeof_is")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HTypeofIs* b = HTypeofIs::cast(other);
     return type_literal_.is_identical_to(b->type_literal_);
   }
 
  private:
   Handle<String> type_literal_;
 };
 
 
-class HInstanceOf: public HBinaryOperation {
+class HInstanceOf: public HTemplateInstruction<3> {
  public:
-  HInstanceOf(HValue* left, HValue* right) : HBinaryOperation(left, right) {
+  HInstanceOf(HValue* context, HValue* left, HValue* right) {
+    SetOperandAt(0, context);
+    SetOperandAt(1, left);
+    SetOperandAt(2, right);
     set_representation(Representation::Tagged());
     SetAllSideEffects();
   }
 
-  virtual bool EmitAtUses() const { return uses()->length() <= 1; }
+  HValue* context() { return OperandAt(0); }
+  HValue* left() { return OperandAt(1); }
+  HValue* right() { return OperandAt(2); }
+
+  virtual bool EmitAtUses() const {
+    return !HasSideEffects() && (uses()->length() <= 1);
+  }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
+  virtual void PrintDataTo(StringStream* stream);
+
   DECLARE_CONCRETE_INSTRUCTION(InstanceOf, "instance_of")
 };
 
 
 class HInstanceOfKnownGlobal: public HUnaryOperation {
  public:
   HInstanceOfKnownGlobal(HValue* left, Handle<JSFunction> right)
       : HUnaryOperation(left), function_(right) {
     set_representation(Representation::Tagged());
     SetAllSideEffects();
@@ skipping 21 matching lines @@
     SetFlag(kUseGVN);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return (index == 1) ? Representation::None() : Representation::Double();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(Power, "power")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HAdd: public HArithmeticBinaryOperation {
  public:
   HAdd(HValue* left, HValue* right) : HArithmeticBinaryOperation(left, right) {
     SetFlag(kCanOverflow);
   }
 
   // Add is only commutative if two integer values are added and not if two
   // tagged values are added (because it might be a String concatenation).
   virtual bool IsCommutative() const {
     return !representation().IsTagged();
   }
 
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited);
 
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(Add, "add")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HSub: public HArithmeticBinaryOperation {
  public:
   HSub(HValue* left, HValue* right) : HArithmeticBinaryOperation(left, right) {
     SetFlag(kCanOverflow);
   }
 
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited);
 
   DECLARE_CONCRETE_INSTRUCTION(Sub, "sub")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HMul: public HArithmeticBinaryOperation {
  public:
   HMul(HValue* left, HValue* right) : HArithmeticBinaryOperation(left, right) {
     SetFlag(kCanOverflow);
   }
 
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited);
 
   // Only commutative if it is certain that not two objects are multiplicated.
   virtual bool IsCommutative() const {
     return !representation().IsTagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(Mul, "mul")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HMod: public HArithmeticBinaryOperation {
  public:
   HMod(HValue* left, HValue* right) : HArithmeticBinaryOperation(left, right) {
     SetFlag(kCanBeDivByZero);
   }
 
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited);
 
   DECLARE_CONCRETE_INSTRUCTION(Mod, "mod")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HDiv: public HArithmeticBinaryOperation {
  public:
   HDiv(HValue* left, HValue* right) : HArithmeticBinaryOperation(left, right) {
     SetFlag(kCanBeDivByZero);
     SetFlag(kCanOverflow);
   }
 
   virtual HValue* EnsureAndPropagateNotMinusZero(BitVector* visited);
 
   DECLARE_CONCRETE_INSTRUCTION(Div, "div")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HBitAnd: public HBitwiseBinaryOperation {
  public:
   HBitAnd(HValue* left, HValue* right)
       : HBitwiseBinaryOperation(left, right) { }
 
   virtual bool IsCommutative() const { return true; }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(BitAnd, "bit_and")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HBitXor: public HBitwiseBinaryOperation {
  public:
   HBitXor(HValue* left, HValue* right)
       : HBitwiseBinaryOperation(left, right) { }
 
   virtual bool IsCommutative() const { return true; }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(BitXor, "bit_xor")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HBitOr: public HBitwiseBinaryOperation {
  public:
   HBitOr(HValue* left, HValue* right)
       : HBitwiseBinaryOperation(left, right) { }
 
   virtual bool IsCommutative() const { return true; }
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(BitOr, "bit_or")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange();
 };
 
 
 class HShl: public HBitwiseBinaryOperation {
  public:
   HShl(HValue* left, HValue* right)
       : HBitwiseBinaryOperation(left, right) { }
 
   virtual Range* InferRange();
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(Shl, "shl")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HShr: public HBitwiseBinaryOperation {
  public:
   HShr(HValue* left, HValue* right)
       : HBitwiseBinaryOperation(left, right) { }
 
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(Shr, "shr")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
 class HSar: public HBitwiseBinaryOperation {
  public:
   HSar(HValue* left, HValue* right)
       : HBitwiseBinaryOperation(left, right) { }
 
   virtual Range* InferRange();
-  virtual HType CalculateInferredType() const;
+  virtual HType CalculateInferredType();
 
   DECLARE_CONCRETE_INSTRUCTION(Sar, "sar")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HOsrEntry: public HInstruction {
+class HOsrEntry: public HTemplateInstruction<0> {
  public:
   explicit HOsrEntry(int ast_id) : ast_id_(ast_id) {
     SetFlag(kChangesOsrEntries);
   }
 
   int ast_id() const { return ast_id_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(OsrEntry, "osr_entry")
 
  private:
   int ast_id_;
 };
 
 
-class HParameter: public HInstruction {
+class HParameter: public HTemplateInstruction<0> {
  public:
   explicit HParameter(unsigned index) : index_(index) {
     set_representation(Representation::Tagged());
   }
 
   unsigned index() const { return index_; }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(Parameter, "parameter")
 
  private:
   unsigned index_;
 };
 
 
-class HCallStub: public HInstruction {
+class HCallStub: public HUnaryCall {
  public:
-  HCallStub(CodeStub::Major major_key, int argument_count)
-      : major_key_(major_key),
-        argument_count_(argument_count),
+  HCallStub(HValue* context, CodeStub::Major major_key, int argument_count)
+      : HUnaryCall(context, argument_count),
+        major_key_(major_key),
         transcendental_type_(TranscendentalCache::kNumberOfCaches) {
-    set_representation(Representation::Tagged());
-    SetAllSideEffects();
   }
 
   CodeStub::Major major_key() { return major_key_; }
-  int argument_count() { return argument_count_; }
+
+  HValue* context() { return value(); }
 
   void set_transcendental_type(TranscendentalCache::Type transcendental_type) {
     transcendental_type_ = transcendental_type;
   }
   TranscendentalCache::Type transcendental_type() {
     return transcendental_type_;
   }
-  virtual void PrintDataTo(StringStream* stream) const;
+
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
 
   DECLARE_CONCRETE_INSTRUCTION(CallStub, "call_stub")
 
  private:
   CodeStub::Major major_key_;
-  int argument_count_;
   TranscendentalCache::Type transcendental_type_;
 };
 
 
-class HUnknownOSRValue: public HInstruction {
+class HUnknownOSRValue: public HTemplateInstruction<0> {
  public:
   HUnknownOSRValue() { set_representation(Representation::Tagged()); }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(UnknownOSRValue, "unknown_osr_value")
 };
 
 
-class HLoadGlobal: public HInstruction {
+class HLoadGlobal: public HTemplateInstruction<0> {
  public:
   HLoadGlobal(Handle<JSGlobalPropertyCell> cell, bool check_hole_value)
       : cell_(cell), check_hole_value_(check_hole_value) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     SetFlag(kDependsOnGlobalVars);
   }
 
   Handle<JSGlobalPropertyCell>  cell() const { return cell_; }
   bool check_hole_value() const { return check_hole_value_; }
 
-  virtual Representation RequiredInputRepresentation(int index) const {
-    return Representation::Tagged();
-  }
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
-  virtual intptr_t Hashcode() const {
+  virtual intptr_t Hashcode() {
     ASSERT(!HEAP->allow_allocation(false));
     return reinterpret_cast<intptr_t>(*cell_);
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(LoadGlobal, "load_global")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HLoadGlobal* b = HLoadGlobal::cast(other);
     return cell_.is_identical_to(b->cell());
   }
 
  private:
   Handle<JSGlobalPropertyCell> cell_;
   bool check_hole_value_;
 };
 
 
 class HStoreGlobal: public HUnaryOperation {
  public:
   HStoreGlobal(HValue* value,
                Handle<JSGlobalPropertyCell> cell,
                bool check_hole_value)
       : HUnaryOperation(value),
         cell_(cell),
         check_hole_value_(check_hole_value) {
     SetFlag(kChangesGlobalVars);
   }
 
   Handle<JSGlobalPropertyCell> cell() const { return cell_; }
   bool check_hole_value() const { return check_hole_value_; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(StoreGlobal, "store_global")
 
  private:
   Handle<JSGlobalPropertyCell> cell_;
   bool check_hole_value_;
 };
 
 
 class HLoadContextSlot: public HUnaryOperation {
  public:
   HLoadContextSlot(HValue* context , int slot_index)
       : HUnaryOperation(context), slot_index_(slot_index) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     SetFlag(kDependsOnContextSlots);
   }
 
   int slot_index() const { return slot_index_; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(LoadContextSlot, "load_context_slot")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HLoadContextSlot* b = HLoadContextSlot::cast(other);
     return (slot_index() == b->slot_index());
   }
 
  private:
   int slot_index_;
 };
 
 
 static inline bool StoringValueNeedsWriteBarrier(HValue* value) {
   return !value->type().IsSmi() &&
       !(value->IsConstant() && HConstant::cast(value)->InOldSpace());
 }
 
 
 class HStoreContextSlot: public HBinaryOperation {
  public:
   HStoreContextSlot(HValue* context, int slot_index, HValue* value)
       : HBinaryOperation(context, value), slot_index_(slot_index) {
     SetFlag(kChangesContextSlots);
   }
 
-  HValue* context() const { return OperandAt(0); }
-  HValue* value() const { return OperandAt(1); }
+  HValue* context() { return OperandAt(0); }
+  HValue* value() { return OperandAt(1); }
   int slot_index() const { return slot_index_; }
 
-  bool NeedsWriteBarrier() const {
+  bool NeedsWriteBarrier() {
     return StoringValueNeedsWriteBarrier(value());
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(StoreContextSlot, "store_context_slot")
 
  private:
   int slot_index_;
 };
 
 
 class HLoadNamedField: public HUnaryOperation {
  public:
   HLoadNamedField(HValue* object, bool is_in_object, int offset)
       : HUnaryOperation(object),
         is_in_object_(is_in_object),
         offset_(offset) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     if (is_in_object) {
       SetFlag(kDependsOnInobjectFields);
     } else {
       SetFlag(kDependsOnBackingStoreFields);
     }
   }
 
-  HValue* object() const { return OperandAt(0); }
+  HValue* object() { return OperandAt(0); }
   bool is_in_object() const { return is_in_object_; }
   int offset() const { return offset_; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
   DECLARE_CONCRETE_INSTRUCTION(LoadNamedField, "load_named_field")
 
  protected:
-  virtual bool DataEquals(HValue* other) const {
+  virtual bool DataEquals(HValue* other) {
     HLoadNamedField* b = HLoadNamedField::cast(other);
     return is_in_object_ == b->is_in_object_ && offset_ == b->offset_;
   }
 
  private:
   bool is_in_object_;
   int offset_;
 };
 
 
-class HLoadNamedGeneric: public HUnaryOperation {
+class HLoadNamedGeneric: public HBinaryOperation {
  public:
-  HLoadNamedGeneric(HValue* object, Handle<Object> name)
-      : HUnaryOperation(object), name_(name) {
+  HLoadNamedGeneric(HValue* context, HValue* object, Handle<Object> name)
+      : HBinaryOperation(context, object), name_(name) {
     set_representation(Representation::Tagged());
     SetAllSideEffects();
   }
 
-  HValue* object() const { return OperandAt(0); }
+  HValue* context() { return OperandAt(0); }
+  HValue* object() { return OperandAt(1); }
   Handle<Object> name() const { return name_; }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(LoadNamedGeneric, "load_named_generic")
 
  private:
   Handle<Object> name_;
 };
 
 
 class HLoadFunctionPrototype: public HUnaryOperation {
  public:
   explicit HLoadFunctionPrototype(HValue* function)
       : HUnaryOperation(function) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
     SetFlag(kDependsOnCalls);
   }
 
-  HValue* function() const { return OperandAt(0); }
+  HValue* function() { return OperandAt(0); }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(LoadFunctionPrototype, "load_function_prototype")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HLoadKeyed: public HBinaryOperation {
+class HLoadKeyedFastElement: public HBinaryOperation {
  public:
-  HLoadKeyed(HValue* obj, HValue* key) : HBinaryOperation(obj, key) {
+  HLoadKeyedFastElement(HValue* obj, HValue* key) : HBinaryOperation(obj, key) {
     set_representation(Representation::Tagged());
-  }
-
-  virtual void PrintDataTo(StringStream* stream) const;
-
-  virtual Representation RequiredInputRepresentation(int index) const {
-    return Representation::Tagged();
-  }
-  HValue* object() const { return OperandAt(0); }
-  HValue* key() const { return OperandAt(1); }
-
-  DECLARE_INSTRUCTION(LoadKeyed)
-};
-
-
-class HLoadKeyedFastElement: public HLoadKeyed {
- public:
-  HLoadKeyedFastElement(HValue* obj, HValue* key) : HLoadKeyed(obj, key) {
     SetFlag(kDependsOnArrayElements);
     SetFlag(kUseGVN);
   }
 
+  HValue* object() { return OperandAt(0); }
+  HValue* key() { return OperandAt(1); }
+
   virtual Representation RequiredInputRepresentation(int index) const {
     // The key is supposed to be Integer32.
     return (index == 1) ? Representation::Integer32()
         : Representation::Tagged();
   }
 
+  virtual void PrintDataTo(StringStream* stream);
+
   DECLARE_CONCRETE_INSTRUCTION(LoadKeyedFastElement,
                                "load_keyed_fast_element")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 };
 
 
-class HLoadKeyedGeneric: public HLoadKeyed {
+class HLoadPixelArrayElement: public HBinaryOperation {
  public:
-  HLoadKeyedGeneric(HValue* obj, HValue* key) : HLoadKeyed(obj, key) {
+  HLoadPixelArrayElement(HValue* external_elements, HValue* key)
+      : HBinaryOperation(external_elements, key) {
+    set_representation(Representation::Integer32());
+    SetFlag(kDependsOnPixelArrayElements);
+    // Native code could change the pixel array.
+    SetFlag(kDependsOnCalls);
+    SetFlag(kUseGVN);
+  }
+
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    // The key is supposed to be Integer32, but the base pointer
+    // for the element load is a naked pointer.
+    return (index == 1) ? Representation::Integer32()
+        : Representation::External();
+  }
+
+  HValue* external_pointer() { return OperandAt(0); }
+  HValue* key() { return OperandAt(1); }
+
+  DECLARE_CONCRETE_INSTRUCTION(LoadPixelArrayElement,
+                               "load_pixel_array_element")
+
+ protected:
+  virtual bool DataEquals(HValue* other) { return true; }
+};
+
+
+class HLoadKeyedGeneric: public HTemplateInstruction<3> {
+ public:
+  HLoadKeyedGeneric(HContext* context, HValue* obj, HValue* key) {
+    set_representation(Representation::Tagged());
+    SetOperandAt(0, obj);
+    SetOperandAt(1, key);
+    SetOperandAt(2, context);
     SetAllSideEffects();
   }
 
+  HValue* object() { return OperandAt(0); }
+  HValue* key() { return OperandAt(1); }
+  HValue* context() { return OperandAt(2); }
+
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(LoadKeyedGeneric, "load_keyed_generic")
 };
 
 
-class HStoreNamed: public HBinaryOperation {
- public:
-  HStoreNamed(HValue* obj, Handle<Object> name, HValue* val)
-      : HBinaryOperation(obj, val), name_(name) {
-  }
-
-  virtual Representation RequiredInputRepresentation(int index) const {
-    return Representation::Tagged();
-  }
-
-  virtual void PrintDataTo(StringStream* stream) const;
-
-  HValue* object() const { return OperandAt(0); }
-  Handle<Object> name() const { return name_; }
-  HValue* value() const { return OperandAt(1); }
-  void set_value(HValue* value) { SetOperandAt(1, value); }
-
-  DECLARE_INSTRUCTION(StoreNamed)
-
- private:
-  Handle<Object> name_;
-};
-
-
-class HStoreNamedField: public HStoreNamed {
+class HStoreNamedField: public HBinaryOperation {
  public:
   HStoreNamedField(HValue* obj,
-                   Handle<Object> name,
+                   Handle<String> name,
                    HValue* val,
                    bool in_object,
                    int offset)
-      : HStoreNamed(obj, name, val),
+      : HBinaryOperation(obj, val),
+        name_(name),
         is_in_object_(in_object),
         offset_(offset) {
     if (is_in_object_) {
       SetFlag(kChangesInobjectFields);
     } else {
       SetFlag(kChangesBackingStoreFields);
     }
   }
 
   DECLARE_CONCRETE_INSTRUCTION(StoreNamedField, "store_named_field")
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
-  virtual void PrintDataTo(StringStream* stream) const;
+  virtual void PrintDataTo(StringStream* stream);
 
+  HValue* object() { return OperandAt(0); }
+  HValue* value() { return OperandAt(1); }
+
+  Handle<String> name() const { return name_; }
   bool is_in_object() const { return is_in_object_; }
   int offset() const { return offset_; }
   Handle<Map> transition() const { return transition_; }
   void set_transition(Handle<Map> map) { transition_ = map; }
 
-  bool NeedsWriteBarrier() const {
+  bool NeedsWriteBarrier() {
     return StoringValueNeedsWriteBarrier(value());
   }
 
  private:
+  Handle<String> name_;
   bool is_in_object_;
   int offset_;
   Handle<Map> transition_;
 };
 
 
-class HStoreNamedGeneric: public HStoreNamed {
+class HStoreNamedGeneric: public HTemplateInstruction<3> {
  public:
-  HStoreNamedGeneric(HValue* obj, Handle<Object> name, HValue* val)
-      : HStoreNamed(obj, name, val) {
+  HStoreNamedGeneric(HValue* context,
+                     HValue* object,
+                     Handle<String> name,
+                     HValue* value)
+      : name_(name) {
+    SetOperandAt(0, object);
+    SetOperandAt(1, value);
+    SetOperandAt(2, context);
     SetAllSideEffects();
   }
 
-  DECLARE_CONCRETE_INSTRUCTION(StoreNamedGeneric, "store_named_generic")
-};
+  HValue* object() { return OperandAt(0); }
+  HValue* value() { return OperandAt(1); }
+  HValue* context() { return OperandAt(2); }
+  Handle<String> name() { return name_; }
 
-
-class HStoreKeyed: public HInstruction {
- public:
-  HStoreKeyed(HValue* obj, HValue* key, HValue* val) {
-    SetOperandAt(0, obj);
-    SetOperandAt(1, key);
-    SetOperandAt(2, val);
-  }
-
-  virtual void PrintDataTo(StringStream* stream) const;
-  virtual int OperandCount() const { return operands_.length(); }
-  virtual HValue* OperandAt(int index) const { return operands_[index]; }
+  virtual void PrintDataTo(StringStream* stream);
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  HValue* object() const { return OperandAt(0); }
-  HValue* key() const { return OperandAt(1); }
-  HValue* value() const { return OperandAt(2); }
-
-  bool NeedsWriteBarrier() const {
-    return StoringValueNeedsWriteBarrier(value());
-  }
-
-  DECLARE_INSTRUCTION(StoreKeyed)
-
- protected:
-  virtual void InternalSetOperandAt(int index, HValue* value) {
-    operands_[index] = value;
-  }
+  DECLARE_CONCRETE_INSTRUCTION(StoreNamedGeneric, "store_named_generic")
 
  private:
-  HOperandVector<3> operands_;
+  Handle<String> name_;
 };
 
 
-class HStoreKeyedFastElement: public HStoreKeyed {
+class HStoreKeyedFastElement: public HTemplateInstruction<3> {
  public:
-  HStoreKeyedFastElement(HValue* obj, HValue* key, HValue* val)
-      : HStoreKeyed(obj, key, val) {
+  HStoreKeyedFastElement(HValue* obj, HValue* key, HValue* val) {
+    SetOperandAt(0, obj);
+    SetOperandAt(1, key);
+    SetOperandAt(2, val);
     SetFlag(kChangesArrayElements);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     // The key is supposed to be Integer32.
     return (index == 1) ? Representation::Integer32()
         : Representation::Tagged();
   }
 
+  HValue* object() { return OperandAt(0); }
+  HValue* key() { return OperandAt(1); }
+  HValue* value() { return OperandAt(2); }
+
+  bool NeedsWriteBarrier() {
+    return StoringValueNeedsWriteBarrier(value());
+  }
+
+  virtual void PrintDataTo(StringStream* stream);
+
   DECLARE_CONCRETE_INSTRUCTION(StoreKeyedFastElement,
                                "store_keyed_fast_element")
 };
 
 
-class HStoreKeyedGeneric: public HStoreKeyed {
+class HStorePixelArrayElement: public HTemplateInstruction<3> {
  public:
-  HStoreKeyedGeneric(HValue* obj, HValue* key, HValue* val)
-      : HStoreKeyed(obj, key, val) {
+  HStorePixelArrayElement(HValue* external_elements, HValue* key, HValue* val) {
+    SetFlag(kChangesPixelArrayElements);
+    SetOperandAt(0, external_elements);
+    SetOperandAt(1, key);
+    SetOperandAt(2, val);
+  }
+
+  virtual void PrintDataTo(StringStream* stream);
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    if (index == 0) {
+      return Representation::External();
+    } else {
+      return Representation::Integer32();
+    }
+  }
+
+  HValue* external_pointer() { return OperandAt(0); }
+  HValue* key() { return OperandAt(1); }
+  HValue* value() { return OperandAt(2); }
+
+  DECLARE_CONCRETE_INSTRUCTION(StorePixelArrayElement,
+                               "store_pixel_array_element")
+};
+
+
+class HStoreKeyedGeneric: public HTemplateInstruction<4> {
+ public:
+  HStoreKeyedGeneric(HValue* context,
+                     HValue* object,
+                     HValue* key,
+                     HValue* value) {
+    SetOperandAt(0, object);
+    SetOperandAt(1, key);
+    SetOperandAt(2, value);
+    SetOperandAt(3, context);
     SetAllSideEffects();
   }
 
+  HValue* object() { return OperandAt(0); }
+  HValue* key() { return OperandAt(1); }
+  HValue* value() { return OperandAt(2); }
+  HValue* context() { return OperandAt(3); }
+
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
+  virtual void PrintDataTo(StringStream* stream);
+
   DECLARE_CONCRETE_INSTRUCTION(StoreKeyedGeneric, "store_keyed_generic")
 };
 
 
 class HStringCharCodeAt: public HBinaryOperation {
  public:
   HStringCharCodeAt(HValue* string, HValue* index)
       : HBinaryOperation(string, index) {
     set_representation(Representation::Integer32());
     SetFlag(kUseGVN);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     // The index is supposed to be Integer32.
     return (index == 1) ? Representation::Integer32()
         : Representation::Tagged();
   }
 
-  HValue* string() const { return OperandAt(0); }
-  HValue* index() const { return OperandAt(1); }
+  HValue* string() { return OperandAt(0); }
+  HValue* index() { return OperandAt(1); }
 
   DECLARE_CONCRETE_INSTRUCTION(StringCharCodeAt, "string_char_code_at")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange() {
     return new Range(0, String::kMaxUC16CharCode);
   }
 };
 
 
 class HStringLength: public HUnaryOperation {
  public:
   explicit HStringLength(HValue* string) : HUnaryOperation(string) {
     set_representation(Representation::Tagged());
     SetFlag(kUseGVN);
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
-  virtual HType CalculateInferredType() const {
+  virtual HType CalculateInferredType() {
     STATIC_ASSERT(String::kMaxLength <= Smi::kMaxValue);
     return HType::Smi();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(StringLength, "string_length")
 
  protected:
-  virtual bool DataEquals(HValue* other) const { return true; }
+  virtual bool DataEquals(HValue* other) { return true; }
 
   virtual Range* InferRange() {
     return new Range(0, String::kMaxLength);
   }
 };
 
 
-class HMaterializedLiteral: public HInstruction {
+template <int V>
+class HMaterializedLiteral: public HTemplateInstruction<V> {
  public:
-  HMaterializedLiteral(int index, int depth)
+  HMaterializedLiteral<V>(int index, int depth)
       : literal_index_(index), depth_(depth) {
-    set_representation(Representation::Tagged());
+    this->set_representation(Representation::Tagged());
   }
 
   int literal_index() const { return literal_index_; }
   int depth() const { return depth_; }
 
-  DECLARE_INSTRUCTION(MaterializedLiteral)
-
  private:
   int literal_index_;
   int depth_;
 };
 
 
-class HArrayLiteral: public HMaterializedLiteral {
+class HArrayLiteral: public HMaterializedLiteral<0> {
  public:
   HArrayLiteral(Handle<FixedArray> constant_elements,
                 int length,
                 int literal_index,
                 int depth)
-      : HMaterializedLiteral(literal_index, depth),
+      : HMaterializedLiteral<0>(literal_index, depth),
         length_(length),
         constant_elements_(constant_elements) {}
 
   Handle<FixedArray> constant_elements() const { return constant_elements_; }
   int length() const { return length_; }
 
   bool IsCopyOnWrite() const;
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(ArrayLiteral, "array_literal")
 
  private:
   int length_;
   Handle<FixedArray> constant_elements_;
 };
 
 
-class HObjectLiteral: public HMaterializedLiteral {
+class HObjectLiteral: public HMaterializedLiteral<1> {
  public:
-  HObjectLiteral(Handle<FixedArray> constant_properties,
+  HObjectLiteral(HValue* context,
+                 Handle<FixedArray> constant_properties,
                  bool fast_elements,
                  int literal_index,
                  int depth)
-      : HMaterializedLiteral(literal_index, depth),
+      : HMaterializedLiteral<1>(literal_index, depth),
         constant_properties_(constant_properties),
-        fast_elements_(fast_elements) {}
+        fast_elements_(fast_elements) {
+    SetOperandAt(0, context);
+  }
 
+  HValue* context() { return OperandAt(0); }
   Handle<FixedArray> constant_properties() const {
     return constant_properties_;
   }
   bool fast_elements() const { return fast_elements_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(ObjectLiteral, "object_literal")
 
  private:
   Handle<FixedArray> constant_properties_;
   bool fast_elements_;
 };
 
 
-class HRegExpLiteral: public HMaterializedLiteral {
+class HRegExpLiteral: public HMaterializedLiteral<0> {
  public:
   HRegExpLiteral(Handle<String> pattern,
                  Handle<String> flags,
                  int literal_index)
-      : HMaterializedLiteral(literal_index, 0),
+      : HMaterializedLiteral<0>(literal_index, 0),
         pattern_(pattern),
         flags_(flags) { }
 
   Handle<String> pattern() { return pattern_; }
   Handle<String> flags() { return flags_; }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(RegExpLiteral, "regexp_literal")
 
  private:
   Handle<String> pattern_;
   Handle<String> flags_;
 };
 
 
-class HFunctionLiteral: public HInstruction {
+class HFunctionLiteral: public HTemplateInstruction<0> {
  public:
   HFunctionLiteral(Handle<SharedFunctionInfo> shared, bool pretenure)
       : shared_info_(shared), pretenure_(pretenure) {
     set_representation(Representation::Tagged());
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::None();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(FunctionLiteral, "function_literal")
 
   Handle<SharedFunctionInfo> shared_info() const { return shared_info_; }
   bool pretenure() const { return pretenure_; }
 
  private:
   Handle<SharedFunctionInfo> shared_info_;
   bool pretenure_;
 };
 
@@ skipping 11 matching lines @@
   DECLARE_CONCRETE_INSTRUCTION(Typeof, "typeof")
 };
 
 
 class HValueOf: public HUnaryOperation {
  public:
   explicit HValueOf(HValue* value) : HUnaryOperation(value) {
     set_representation(Representation::Tagged());
   }
 
+  virtual Representation RequiredInputRepresentation(int index) const {
+    return Representation::Tagged();
+  }
+
   DECLARE_CONCRETE_INSTRUCTION(ValueOf, "value_of")
 };
 
 
 class HDeleteProperty: public HBinaryOperation {
  public:
   HDeleteProperty(HValue* obj, HValue* key)
       : HBinaryOperation(obj, key) {
     set_representation(Representation::Tagged());
     SetAllSideEffects();
   }
 
   virtual Representation RequiredInputRepresentation(int index) const {
     return Representation::Tagged();
   }
 
   DECLARE_CONCRETE_INSTRUCTION(DeleteProperty, "delete_property")
 
-  HValue* object() const { return left(); }
-  HValue* key() const { return right(); }
+  HValue* object() { return left(); }
+  HValue* key() { return right(); }
 };
 
 #undef DECLARE_INSTRUCTION
 #undef DECLARE_CONCRETE_INSTRUCTION
 
 } }  // namespace v8::internal
 
 #endif  // V8_HYDROGEN_INSTRUCTIONS_H_