runtime/vm/locations.h - sdk.git - Git at Google

 // Copyright (c) 2013, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef VM_LOCATIONS_H_
 #define VM_LOCATIONS_H_

 #include "vm/allocation.h"
 #include "vm/assembler.h"
 #include "vm/bitfield.h"

 namespace dart {


 class BufferFormatter;
 class ConstantInstr;
 class Definition;
 class PairLocation;
 class Value;


 enum Representation {
   kNoRepresentation,
   kTagged,
   kUntagged,
   kUnboxedDouble,
   kUnboxedInt32,
   kUnboxedUint32,
   kUnboxedMint,
   kUnboxedFloat32x4,
   kUnboxedInt32x4,
   kUnboxedFloat64x2,
   kPairOfTagged,
   kPairOfUnboxedDouble,
   kNumRepresentations
 };


 // Location objects are used to connect register allocator and code generator.
 // Instruction templates used by code generator have a corresponding
 // LocationSummary object which specifies expected location for every input
 // and output.
 // Each location is encoded as a single word: for non-constant locations
 // low 4 bits denote location kind, rest is kind specific location payload
 // e.g. for REGISTER kind payload is register code (value of the Register
 // enumeration), constant locations contain a tagged (low 2 bits are set to 01)
 // Object handle.
 //
 // Locations must satisfy the following invariant: if two locations' encodings
 // are bitwise unequal then these two locations are guaranteed to be disjoint.
 // Properties like representation belong to the value that is stored in
 // the location not to the location itself.
 class Location : public ValueObject {
  private:
   enum {
     // Number of bits required to encode Kind value.
     kBitsForKind = 4,
     kBitsForPayload = kWordSize * kBitsPerByte - kBitsForKind,
   };

   static const uword kInvalidLocation = 0;
   static const uword kLocationTagMask = 0x3;

  public:
   // Constant payload can overlap with kind field so Kind values
   // have to be chosen in a way that their last 2 bits are never
   // the same as kConstantTag or kPairLocationTag.
   // Note that two locations with different kinds should never point to
   // the same place. For example kQuadStackSlot location should never intersect
   // with kDoubleStackSlot location.
   enum Kind {
     // This location is invalid.  Payload must be zero.
     kInvalid = 0,

     // Constant value. This location contains a tagged Object handle.
     kConstantTag = 1,

     // This location contains a tagged pointer to a PairLocation.
     kPairLocationTag = 2,

     // Unallocated location represents a location that is not fixed and can be
     // allocated by a register allocator.  Each unallocated location has
     // a policy that specifies what kind of location is suitable. Payload
     // contains register allocation policy.
     kUnallocated = 3,

     // Spill slots allocated by the register allocator.  Payload contains
     // a spill index.
     kStackSlot = 4,  // Word size slot.
     kDoubleStackSlot = 7,  // 64bit stack slot.
     kQuadStackSlot = 11,  // 128bit stack slot.

     // Register location represents a fixed register.  Payload contains
     // register code.
     kRegister = 8,

     // FpuRegister location represents a fixed fpu register.  Payload contains
     // its code.
     kFpuRegister = 12,
   };

   Location() : value_(kInvalidLocation) {
     // Verify that non-tagged location kinds do not interfere with location tags
     // (kConstantTag and kPairLocationTag).
     COMPILE_ASSERT((kInvalid & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kInvalid & kLocationTagMask) != kPairLocationTag);

     COMPILE_ASSERT((kUnallocated & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kUnallocated & kLocationTagMask) != kPairLocationTag);

     COMPILE_ASSERT((kStackSlot & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kStackSlot & kLocationTagMask) != kPairLocationTag);

     COMPILE_ASSERT((kDoubleStackSlot & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kDoubleStackSlot & kLocationTagMask) != kPairLocationTag);

     COMPILE_ASSERT((kQuadStackSlot & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kQuadStackSlot & kLocationTagMask) != kPairLocationTag);

     COMPILE_ASSERT((kRegister & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kRegister & kLocationTagMask) != kPairLocationTag);

     COMPILE_ASSERT((kFpuRegister & kLocationTagMask) != kConstantTag);
     COMPILE_ASSERT((kFpuRegister & kLocationTagMask) != kPairLocationTag);

     // Verify tags and tagmask.
     COMPILE_ASSERT((kConstantTag & kLocationTagMask) == kConstantTag);

     COMPILE_ASSERT((kPairLocationTag & kLocationTagMask) == kPairLocationTag);

     ASSERT(IsInvalid());
   }

   Location(const Location& other) : ValueObject(), value_(other.value_) { }

   Location& operator=(const Location& other) {
     value_ = other.value_;
     return *this;
   }

   bool IsInvalid() const {
     return value_ == kInvalidLocation;
   }

   // Constants.
   bool IsConstant() const {
     return (value_ & kLocationTagMask) == kConstantTag;
   }

   static Location Constant(ConstantInstr* obj) {
     Location loc(reinterpret_cast<uword>(obj) | kConstantTag);
     ASSERT(obj == loc.constant_instruction());
     return loc;
   }

   ConstantInstr* constant_instruction() const {
     ASSERT(IsConstant());
     return reinterpret_cast<ConstantInstr*>(value_ & ~kLocationTagMask);
   }

   const Object& constant() const;

   bool IsPairLocation() const {
     return (value_ & kLocationTagMask) == kPairLocationTag;
   }

   static Location Pair(Location first, Location second);

   PairLocation* AsPairLocation() const;

   // Unallocated locations.
   enum Policy {
     kAny,
     kPrefersRegister,
     kRequiresRegister,
     kRequiresFpuRegister,
     kWritableRegister,
     kSameAsFirstInput,
   };

   bool IsUnallocated() const {
     return kind() == kUnallocated;
   }

   bool IsRegisterBeneficial() {
     return !Equals(Any());
   }

   static Location UnallocatedLocation(Policy policy) {
     return Location(kUnallocated, PolicyField::encode(policy));
   }

   // Any free register is suitable to replace this unallocated location.
   static Location Any() {
     return UnallocatedLocation(kAny);
   }

   static Location PrefersRegister() {
     return UnallocatedLocation(kPrefersRegister);
   }

   static Location RequiresRegister() {
     return UnallocatedLocation(kRequiresRegister);
   }

   static Location RequiresFpuRegister() {
     return UnallocatedLocation(kRequiresFpuRegister);
   }

   static Location WritableRegister() {
     return UnallocatedLocation(kWritableRegister);
   }

   // The location of the first input to the instruction will be
   // used to replace this unallocated location.
   static Location SameAsFirstInput() {
     return UnallocatedLocation(kSameAsFirstInput);
   }

   // Empty location. Used if there the location should be ignored.
   static Location NoLocation() {
     return Location();
   }

   Policy policy() const {
     ASSERT(IsUnallocated());
     return PolicyField::decode(payload());
   }

   // Register locations.
   static Location RegisterLocation(Register reg) {
     return Location(kRegister, reg);
   }

   bool IsRegister() const {
     return kind() == kRegister;
   }

   Register reg() const {
     ASSERT(IsRegister());
     return static_cast<Register>(payload());
   }

   // FpuRegister locations.
   static Location FpuRegisterLocation(FpuRegister reg) {
     return Location(kFpuRegister, reg);
   }

   bool IsFpuRegister() const {
     return kind() == kFpuRegister;
   }

   FpuRegister fpu_reg() const {
     ASSERT(IsFpuRegister());
     return static_cast<FpuRegister>(payload());
   }

   static bool IsMachineRegisterKind(Kind kind) {
     return (kind == kRegister) || (kind == kFpuRegister);
   }

   static Location MachineRegisterLocation(Kind kind,
                                           intptr_t reg) {
     if (kind == kRegister) {
       return RegisterLocation(static_cast<Register>(reg));
     } else {
       ASSERT(kind == kFpuRegister);
       return FpuRegisterLocation(static_cast<FpuRegister>(reg));
     }
   }

   bool IsMachineRegister() const {
     return IsMachineRegisterKind(kind());
   }

   intptr_t register_code() const {
     ASSERT(IsMachineRegister());
     return static_cast<intptr_t>(payload());
   }

   static uword EncodeStackIndex(intptr_t stack_index) {
     ASSERT((-kStackIndexBias <= stack_index) &&
            (stack_index < kStackIndexBias));
     return static_cast<uword>(kStackIndexBias + stack_index);
   }

   // Spill slots.
   static Location StackSlot(intptr_t stack_index,
                             Register base = FPREG) {
     uword payload = StackSlotBaseField::encode(base)
         | StackIndexField::encode(EncodeStackIndex(stack_index));
     Location loc(kStackSlot, payload);
     // Ensure that sign is preserved.
     ASSERT(loc.stack_index() == stack_index);
     return loc;
   }

   bool IsStackSlot() const {
     return kind() == kStackSlot;
   }

   static Location DoubleStackSlot(intptr_t stack_index) {
     uword payload = StackSlotBaseField::encode(FPREG)
         | StackIndexField::encode(EncodeStackIndex(stack_index));
     Location loc(kDoubleStackSlot, payload);
     // Ensure that sign is preserved.
     ASSERT(loc.stack_index() == stack_index);
     return loc;
   }

   bool IsDoubleStackSlot() const {
     return kind() == kDoubleStackSlot;
   }

   static Location QuadStackSlot(intptr_t stack_index) {
     uword payload = StackSlotBaseField::encode(FPREG)
         | StackIndexField::encode(EncodeStackIndex(stack_index));
     Location loc(kQuadStackSlot, payload);
     // Ensure that sign is preserved.
     ASSERT(loc.stack_index() == stack_index);
     return loc;
   }

   bool IsQuadStackSlot() const {
     return kind() == kQuadStackSlot;
   }

   Register base_reg() const {
     ASSERT(HasStackIndex());
     return StackSlotBaseField::decode(payload());
   }

   intptr_t stack_index() const {
     ASSERT(HasStackIndex());
     // Decode stack index manually to preserve sign.
     return StackIndexField::decode(payload()) - kStackIndexBias;
   }

   bool HasStackIndex() const {
     return IsStackSlot() || IsDoubleStackSlot() || IsQuadStackSlot();
   }

   // Return a memory operand for stack slot locations.
   Address ToStackSlotAddress() const;

   // Returns the offset from the frame pointer for stack slot locations.
   intptr_t ToStackSlotOffset() const;

   // Constants.
   static Location RegisterOrConstant(Value* value);
   static Location RegisterOrSmiConstant(Value* value);
   static Location WritableRegisterOrSmiConstant(Value* value);
   static Location FixedRegisterOrConstant(Value* value, Register reg);
   static Location FixedRegisterOrSmiConstant(Value* value, Register reg);
   static Location AnyOrConstant(Value* value);

   const char* Name() const;
   void PrintTo(BufferFormatter* f) const;
   void Print() const;
   const char* ToCString() const;

   // Compare two locations.
   bool Equals(Location other) const {
     return value_ == other.value_;
   }

   // If current location is constant might return something that
   // is not equal to any Kind.
   Kind kind() const {
     return KindField::decode(value_);
   }

   Location Copy() const;

   Location RemapForSlowPath(Definition* def,
                             intptr_t* cpu_reg_slots,
                             intptr_t* fpu_reg_slots) const;

  private:
   explicit Location(uword value) : value_(value) { }

   Location(Kind kind, uword payload)
       : value_(KindField::encode(kind) | PayloadField::encode(payload)) { }

   uword payload() const {
     return PayloadField::decode(value_);
   }

   typedef BitField<Kind, 0, kBitsForKind> KindField;
   typedef BitField<uword, kBitsForKind, kBitsForPayload> PayloadField;

   // Layout for kUnallocated locations payload.
   typedef BitField<Policy, 0, 3> PolicyField;

   // Layout for stack slots.
   static const intptr_t kBitsForBaseReg = 5;
   static const intptr_t kBitsForStackIndex = kBitsForPayload - kBitsForBaseReg;
   typedef BitField<Register, 0, kBitsForBaseReg> StackSlotBaseField;
   typedef BitField<intptr_t,
                    kBitsForBaseReg,
                    kBitsForStackIndex> StackIndexField;
   COMPILE_ASSERT(1 << kBitsForBaseReg >= kNumberOfCpuRegisters);

   static const intptr_t kStackIndexBias =
       static_cast<intptr_t>(1) << (kBitsForStackIndex - 1);

   // Location either contains kind and payload fields or a tagged handle for
   // a constant locations. Values of enumeration Kind are selected in such a
   // way that none of them can be interpreted as a kConstant tag.
   uword value_;
 };


 class PairLocation : public ZoneAllocated {
  public:
   PairLocation() {
     for (intptr_t i = 0; i < kPairLength; i++) {
       ASSERT(locations_[i].IsInvalid());
     }
   }

   intptr_t length() const { return kPairLength; }

   Location At(intptr_t i) const {
     ASSERT(i >= 0);
     ASSERT(i < kPairLength);
     return locations_[i];
   }

   void SetAt(intptr_t i, Location loc) {
     ASSERT(i >= 0);
     ASSERT(i < kPairLength);
     locations_[i] = loc;
   }

   Location* SlotAt(intptr_t i) {
     ASSERT(i >= 0);
     ASSERT(i < kPairLength);
     return &locations_[i];
   }

  private:
   static const intptr_t kPairLength = 2;
   Location locations_[kPairLength];
 };


 class RegisterSet : public ValueObject {
  public:
   RegisterSet() : cpu_registers_(0), untagged_cpu_registers_(0),
                   fpu_registers_(0) {
     ASSERT(kNumberOfCpuRegisters <= (kWordSize * kBitsPerByte));
     ASSERT(kNumberOfFpuRegisters <= (kWordSize * kBitsPerByte));
   }


   void Add(Location loc, Representation rep = kTagged) {
     if (loc.IsRegister()) {
       cpu_registers_ |= (1 << loc.reg());
       if (rep != kTagged) {
         // CPU register contains an untagged value.
         MarkUntagged(loc);
       }
     } else if (loc.IsFpuRegister()) {
       fpu_registers_ |= (1 << loc.fpu_reg());
     }
   }

   void Remove(Location loc) {
     if (loc.IsRegister()) {
       cpu_registers_ &= ~(1 << loc.reg());
     } else if (loc.IsFpuRegister()) {
       fpu_registers_ &= ~(1 << loc.fpu_reg());
     }
   }

   bool Contains(Location loc) {
     if (loc.IsRegister()) {
       return ContainsRegister(loc.reg());
     } else if (loc.IsFpuRegister()) {
       return ContainsFpuRegister(loc.fpu_reg());
     } else {
       UNREACHABLE();
       return false;
     }
   }

   void DebugPrint() {
     for (intptr_t i = 0; i < kNumberOfCpuRegisters; i++) {
       Register r = static_cast<Register>(i);
       if (ContainsRegister(r)) {
         OS::Print("%s %s\n", Assembler::RegisterName(r),
                            IsTagged(r) ? "tagged" : "untagged");
       }
     }

     for (intptr_t i = 0; i < kNumberOfFpuRegisters; i++) {
       FpuRegister r = static_cast<FpuRegister>(i);
       if (ContainsFpuRegister(r)) {
         OS::Print("%s\n", Assembler::FpuRegisterName(r));
       }
     }
   }

   void MarkUntagged(Location loc) {
     ASSERT(loc.IsRegister());
     untagged_cpu_registers_ |= (1 << loc.reg());
   }

   bool IsTagged(Register reg) const {
     return (untagged_cpu_registers_ & (1 << reg)) == 0;
   }

   bool ContainsRegister(Register reg) const {
     return Contains(cpu_registers_, reg);
   }

   bool ContainsFpuRegister(FpuRegister fpu_reg) const {
     return Contains(fpu_registers_, fpu_reg);
   }

   intptr_t CpuRegisterCount() const { return RegisterCount(cpu_registers_); }
   intptr_t FpuRegisterCount() const { return RegisterCount(fpu_registers_); }

   static intptr_t RegisterCount(intptr_t registers);
   static bool Contains(intptr_t register_set, intptr_t reg) {
     return (register_set & (1 << reg)) != 0;
   }

   intptr_t cpu_registers() const { return cpu_registers_; }
   intptr_t fpu_registers() const { return fpu_registers_; }

  private:
   intptr_t cpu_registers_;
   intptr_t untagged_cpu_registers_;
   intptr_t fpu_registers_;

   DISALLOW_COPY_AND_ASSIGN(RegisterSet);
 };


 // Specification of locations for inputs and output.
 class LocationSummary : public ZoneAllocated {
  public:
   enum ContainsCall {
     kNoCall,
     kCall,
     kCallOnSlowPath
   };

   LocationSummary(Isolate* isolate,
                   intptr_t input_count,
                   intptr_t temp_count,
                   LocationSummary::ContainsCall contains_call);

   intptr_t input_count() const {
     return num_inputs_;
   }

   Location in(intptr_t index) const {
     ASSERT(index >= 0);
     ASSERT(index < num_inputs_);
     return input_locations_[index];
   }

   Location* in_slot(intptr_t index) {
     ASSERT(index >= 0);
     ASSERT(index < num_inputs_);
     return &input_locations_[index];
   }

   void set_in(intptr_t index, Location loc) {
     ASSERT(index >= 0);
     ASSERT(index < num_inputs_);
     ASSERT(!always_calls() || loc.IsMachineRegister());
     input_locations_[index] = loc;
   }

   intptr_t temp_count() const {
     return num_temps_;
   }

   Location temp(intptr_t index) const {
     ASSERT(index >= 0);
     ASSERT(index < num_temps_);
     return temp_locations_[index];
   }

   Location* temp_slot(intptr_t index) {
     ASSERT(index >= 0);
     ASSERT(index < num_temps_);
     return &temp_locations_[index];
   }

   void set_temp(intptr_t index, Location loc) {
     ASSERT(index >= 0);
     ASSERT(index < num_temps_);
     ASSERT(!always_calls() || loc.IsMachineRegister());
     temp_locations_[index] = loc;
   }

   intptr_t output_count() const {
     return 1;
   }

   Location out(intptr_t index) const {
     ASSERT(index == 0);
     return output_location_;
   }

   Location* out_slot(intptr_t index) {
     ASSERT(index == 0);
     return &output_location_;
   }

   void set_out(intptr_t index, Location loc) {
     ASSERT(index == 0);
     ASSERT(!always_calls() ||
            (loc.IsMachineRegister() || loc.IsInvalid() ||
             loc.IsPairLocation()));
     output_location_ = loc;
   }

   BitmapBuilder* stack_bitmap() {
     if (stack_bitmap_ == NULL) {
       stack_bitmap_ = new BitmapBuilder();
     }
     return stack_bitmap_;
   }
   void SetStackBit(intptr_t index) {
     stack_bitmap()->Set(index, true);
   }

   bool always_calls() const {
     return contains_call_ == kCall;
   }

   bool can_call() {
     return contains_call_ != kNoCall;
   }

   bool HasCallOnSlowPath() {
     return can_call() && !always_calls();
   }

   void PrintTo(BufferFormatter* f) const;

   static LocationSummary* Make(Isolate* isolate,
                                intptr_t input_count,
                                Location out,
                                ContainsCall contains_call);

   RegisterSet* live_registers() {
     return &live_registers_;
   }

 #if defined(DEBUG)
   // Debug only verification that ensures that writable registers are correctly
   // preserved on the slow path.
   void DiscoverWritableInputs();
   void CheckWritableInputs();
 #endif

  private:
   const intptr_t num_inputs_;
   Location* input_locations_;
   const intptr_t num_temps_;
   Location* temp_locations_;
   Location output_location_;

   BitmapBuilder* stack_bitmap_;

   const ContainsCall contains_call_;
   RegisterSet live_registers_;

 #if defined(DEBUG)
   intptr_t writable_inputs_;
 #endif
 };


 }  // namespace dart

 #endif  // VM_LOCATIONS_H_
	// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef VM_LOCATIONS_H_
	#define VM_LOCATIONS_H_

	#include "vm/allocation.h"
	#include "vm/assembler.h"
	#include "vm/bitfield.h"

	namespace dart {


	class BufferFormatter;
	class ConstantInstr;
	class Definition;
	class PairLocation;
	class Value;


	enum Representation {
	kNoRepresentation,
	kTagged,
	kUntagged,
	kUnboxedDouble,
	kUnboxedInt32,
	kUnboxedUint32,
	kUnboxedMint,
	kUnboxedFloat32x4,
	kUnboxedInt32x4,
	kUnboxedFloat64x2,
	kPairOfTagged,
	kPairOfUnboxedDouble,
	kNumRepresentations
	};


	// Location objects are used to connect register allocator and code generator.
	// Instruction templates used by code generator have a corresponding
	// LocationSummary object which specifies expected location for every input
	// and output.
	// Each location is encoded as a single word: for non-constant locations
	// low 4 bits denote location kind, rest is kind specific location payload
	// e.g. for REGISTER kind payload is register code (value of the Register
	// enumeration), constant locations contain a tagged (low 2 bits are set to 01)
	// Object handle.
	//
	// Locations must satisfy the following invariant: if two locations' encodings
	// are bitwise unequal then these two locations are guaranteed to be disjoint.
	// Properties like representation belong to the value that is stored in
	// the location not to the location itself.
	class Location : public ValueObject {
	private:
	enum {
	// Number of bits required to encode Kind value.
	kBitsForKind = 4,
	kBitsForPayload = kWordSize * kBitsPerByte - kBitsForKind,
	};

	static const uword kInvalidLocation = 0;
	static const uword kLocationTagMask = 0x3;

	public:
	// Constant payload can overlap with kind field so Kind values
	// have to be chosen in a way that their last 2 bits are never
	// the same as kConstantTag or kPairLocationTag.
	// Note that two locations with different kinds should never point to
	// the same place. For example kQuadStackSlot location should never intersect
	// with kDoubleStackSlot location.
	enum Kind {
	// This location is invalid. Payload must be zero.
	kInvalid = 0,

	// Constant value. This location contains a tagged Object handle.
	kConstantTag = 1,

	// This location contains a tagged pointer to a PairLocation.
	kPairLocationTag = 2,

	// Unallocated location represents a location that is not fixed and can be
	// allocated by a register allocator. Each unallocated location has
	// a policy that specifies what kind of location is suitable. Payload
	// contains register allocation policy.
	kUnallocated = 3,

	// Spill slots allocated by the register allocator. Payload contains
	// a spill index.
	kStackSlot = 4, // Word size slot.
	kDoubleStackSlot = 7, // 64bit stack slot.
	kQuadStackSlot = 11, // 128bit stack slot.

	// Register location represents a fixed register. Payload contains
	// register code.
	kRegister = 8,

	// FpuRegister location represents a fixed fpu register. Payload contains
	// its code.
	kFpuRegister = 12,
	};

	Location() : value_(kInvalidLocation) {
	// Verify that non-tagged location kinds do not interfere with location tags
	// (kConstantTag and kPairLocationTag).
	COMPILE_ASSERT((kInvalid & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kInvalid & kLocationTagMask) != kPairLocationTag);

	COMPILE_ASSERT((kUnallocated & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kUnallocated & kLocationTagMask) != kPairLocationTag);

	COMPILE_ASSERT((kStackSlot & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kStackSlot & kLocationTagMask) != kPairLocationTag);

	COMPILE_ASSERT((kDoubleStackSlot & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kDoubleStackSlot & kLocationTagMask) != kPairLocationTag);

	COMPILE_ASSERT((kQuadStackSlot & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kQuadStackSlot & kLocationTagMask) != kPairLocationTag);

	COMPILE_ASSERT((kRegister & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kRegister & kLocationTagMask) != kPairLocationTag);

	COMPILE_ASSERT((kFpuRegister & kLocationTagMask) != kConstantTag);
	COMPILE_ASSERT((kFpuRegister & kLocationTagMask) != kPairLocationTag);

	// Verify tags and tagmask.
	COMPILE_ASSERT((kConstantTag & kLocationTagMask) == kConstantTag);

	COMPILE_ASSERT((kPairLocationTag & kLocationTagMask) == kPairLocationTag);

	ASSERT(IsInvalid());
	}

	Location(const Location& other) : ValueObject(), value_(other.value_) { }

	Location& operator=(const Location& other) {
	value_ = other.value_;
	return *this;
	}

	bool IsInvalid() const {
	return value_ == kInvalidLocation;
	}

	// Constants.
	bool IsConstant() const {
	return (value_ & kLocationTagMask) == kConstantTag;
	}

	static Location Constant(ConstantInstr* obj) {
	Location loc(reinterpret_cast<uword>(obj) \| kConstantTag);
	ASSERT(obj == loc.constant_instruction());
	return loc;
	}

	ConstantInstr* constant_instruction() const {
	ASSERT(IsConstant());
	return reinterpret_cast<ConstantInstr*>(value_ & ~kLocationTagMask);
	}

	const Object& constant() const;

	bool IsPairLocation() const {
	return (value_ & kLocationTagMask) == kPairLocationTag;
	}

	static Location Pair(Location first, Location second);

	PairLocation* AsPairLocation() const;

	// Unallocated locations.
	enum Policy {
	kAny,
	kPrefersRegister,
	kRequiresRegister,
	kRequiresFpuRegister,
	kWritableRegister,
	kSameAsFirstInput,
	};

	bool IsUnallocated() const {
	return kind() == kUnallocated;
	}

	bool IsRegisterBeneficial() {
	return !Equals(Any());
	}

	static Location UnallocatedLocation(Policy policy) {
	return Location(kUnallocated, PolicyField::encode(policy));
	}

	// Any free register is suitable to replace this unallocated location.
	static Location Any() {
	return UnallocatedLocation(kAny);
	}

	static Location PrefersRegister() {
	return UnallocatedLocation(kPrefersRegister);
	}

	static Location RequiresRegister() {
	return UnallocatedLocation(kRequiresRegister);
	}

	static Location RequiresFpuRegister() {
	return UnallocatedLocation(kRequiresFpuRegister);
	}

	static Location WritableRegister() {
	return UnallocatedLocation(kWritableRegister);
	}

	// The location of the first input to the instruction will be
	// used to replace this unallocated location.
	static Location SameAsFirstInput() {
	return UnallocatedLocation(kSameAsFirstInput);
	}

	// Empty location. Used if there the location should be ignored.
	static Location NoLocation() {
	return Location();
	}

	Policy policy() const {
	ASSERT(IsUnallocated());
	return PolicyField::decode(payload());
	}

	// Register locations.
	static Location RegisterLocation(Register reg) {
	return Location(kRegister, reg);
	}

	bool IsRegister() const {
	return kind() == kRegister;
	}

	Register reg() const {
	ASSERT(IsRegister());
	return static_cast<Register>(payload());
	}

	// FpuRegister locations.
	static Location FpuRegisterLocation(FpuRegister reg) {
	return Location(kFpuRegister, reg);
	}

	bool IsFpuRegister() const {
	return kind() == kFpuRegister;
	}

	FpuRegister fpu_reg() const {
	ASSERT(IsFpuRegister());
	return static_cast<FpuRegister>(payload());
	}

	static bool IsMachineRegisterKind(Kind kind) {
	return (kind == kRegister) \|\| (kind == kFpuRegister);
	}

	static Location MachineRegisterLocation(Kind kind,
	intptr_t reg) {
	if (kind == kRegister) {
	return RegisterLocation(static_cast<Register>(reg));
	} else {
	ASSERT(kind == kFpuRegister);
	return FpuRegisterLocation(static_cast<FpuRegister>(reg));
	}
	}

	bool IsMachineRegister() const {
	return IsMachineRegisterKind(kind());
	}

	intptr_t register_code() const {
	ASSERT(IsMachineRegister());
	return static_cast<intptr_t>(payload());
	}

	static uword EncodeStackIndex(intptr_t stack_index) {
	ASSERT((-kStackIndexBias <= stack_index) &&
	(stack_index < kStackIndexBias));
	return static_cast<uword>(kStackIndexBias + stack_index);
	}

	// Spill slots.
	static Location StackSlot(intptr_t stack_index,
	Register base = FPREG) {
	uword payload = StackSlotBaseField::encode(base)
	\| StackIndexField::encode(EncodeStackIndex(stack_index));
	Location loc(kStackSlot, payload);
	// Ensure that sign is preserved.
	ASSERT(loc.stack_index() == stack_index);
	return loc;
	}

	bool IsStackSlot() const {
	return kind() == kStackSlot;
	}

	static Location DoubleStackSlot(intptr_t stack_index) {
	uword payload = StackSlotBaseField::encode(FPREG)
	\| StackIndexField::encode(EncodeStackIndex(stack_index));
	Location loc(kDoubleStackSlot, payload);
	// Ensure that sign is preserved.
	ASSERT(loc.stack_index() == stack_index);
	return loc;
	}

	bool IsDoubleStackSlot() const {
	return kind() == kDoubleStackSlot;
	}

	static Location QuadStackSlot(intptr_t stack_index) {
	uword payload = StackSlotBaseField::encode(FPREG)
	\| StackIndexField::encode(EncodeStackIndex(stack_index));
	Location loc(kQuadStackSlot, payload);
	// Ensure that sign is preserved.
	ASSERT(loc.stack_index() == stack_index);
	return loc;
	}

	bool IsQuadStackSlot() const {
	return kind() == kQuadStackSlot;
	}

	Register base_reg() const {
	ASSERT(HasStackIndex());
	return StackSlotBaseField::decode(payload());
	}

	intptr_t stack_index() const {
	ASSERT(HasStackIndex());
	// Decode stack index manually to preserve sign.
	return StackIndexField::decode(payload()) - kStackIndexBias;
	}

	bool HasStackIndex() const {
	return IsStackSlot() \|\| IsDoubleStackSlot() \|\| IsQuadStackSlot();
	}

	// Return a memory operand for stack slot locations.
	Address ToStackSlotAddress() const;

	// Returns the offset from the frame pointer for stack slot locations.
	intptr_t ToStackSlotOffset() const;

	// Constants.
	static Location RegisterOrConstant(Value* value);
	static Location RegisterOrSmiConstant(Value* value);
	static Location WritableRegisterOrSmiConstant(Value* value);
	static Location FixedRegisterOrConstant(Value* value, Register reg);
	static Location FixedRegisterOrSmiConstant(Value* value, Register reg);
	static Location AnyOrConstant(Value* value);

	const char* Name() const;
	void PrintTo(BufferFormatter* f) const;
	void Print() const;
	const char* ToCString() const;

	// Compare two locations.
	bool Equals(Location other) const {
	return value_ == other.value_;
	}

	// If current location is constant might return something that
	// is not equal to any Kind.
	Kind kind() const {
	return KindField::decode(value_);
	}

	Location Copy() const;

	Location RemapForSlowPath(Definition* def,
	intptr_t* cpu_reg_slots,
	intptr_t* fpu_reg_slots) const;

	private:
	explicit Location(uword value) : value_(value) { }

	Location(Kind kind, uword payload)
	: value_(KindField::encode(kind) \| PayloadField::encode(payload)) { }

	uword payload() const {
	return PayloadField::decode(value_);
	}

	typedef BitField<Kind, 0, kBitsForKind> KindField;
	typedef BitField<uword, kBitsForKind, kBitsForPayload> PayloadField;

	// Layout for kUnallocated locations payload.
	typedef BitField<Policy, 0, 3> PolicyField;

	// Layout for stack slots.
	static const intptr_t kBitsForBaseReg = 5;
	static const intptr_t kBitsForStackIndex = kBitsForPayload - kBitsForBaseReg;
	typedef BitField<Register, 0, kBitsForBaseReg> StackSlotBaseField;
	typedef BitField<intptr_t,
	kBitsForBaseReg,
	kBitsForStackIndex> StackIndexField;
	COMPILE_ASSERT(1 << kBitsForBaseReg >= kNumberOfCpuRegisters);

	static const intptr_t kStackIndexBias =
	static_cast<intptr_t>(1) << (kBitsForStackIndex - 1);

	// Location either contains kind and payload fields or a tagged handle for
	// a constant locations. Values of enumeration Kind are selected in such a
	// way that none of them can be interpreted as a kConstant tag.
	uword value_;
	};


	class PairLocation : public ZoneAllocated {
	public:
	PairLocation() {
	for (intptr_t i = 0; i < kPairLength; i++) {
	ASSERT(locations_[i].IsInvalid());
	}
	}

	intptr_t length() const { return kPairLength; }

	Location At(intptr_t i) const {
	ASSERT(i >= 0);
	ASSERT(i < kPairLength);
	return locations_[i];
	}

	void SetAt(intptr_t i, Location loc) {
	ASSERT(i >= 0);
	ASSERT(i < kPairLength);
	locations_[i] = loc;
	}

	Location* SlotAt(intptr_t i) {
	ASSERT(i >= 0);
	ASSERT(i < kPairLength);
	return &locations_[i];
	}

	private:
	static const intptr_t kPairLength = 2;
	Location locations_[kPairLength];
	};


	class RegisterSet : public ValueObject {
	public:
	RegisterSet() : cpu_registers_(0), untagged_cpu_registers_(0),
	fpu_registers_(0) {
	ASSERT(kNumberOfCpuRegisters <= (kWordSize * kBitsPerByte));
	ASSERT(kNumberOfFpuRegisters <= (kWordSize * kBitsPerByte));
	}


	void Add(Location loc, Representation rep = kTagged) {
	if (loc.IsRegister()) {
	cpu_registers_ \|= (1 << loc.reg());
	if (rep != kTagged) {
	// CPU register contains an untagged value.
	MarkUntagged(loc);
	}
	} else if (loc.IsFpuRegister()) {
	fpu_registers_ \|= (1 << loc.fpu_reg());
	}
	}

	void Remove(Location loc) {
	if (loc.IsRegister()) {
	cpu_registers_ &= ~(1 << loc.reg());
	} else if (loc.IsFpuRegister()) {
	fpu_registers_ &= ~(1 << loc.fpu_reg());
	}
	}

	bool Contains(Location loc) {
	if (loc.IsRegister()) {
	return ContainsRegister(loc.reg());
	} else if (loc.IsFpuRegister()) {
	return ContainsFpuRegister(loc.fpu_reg());
	} else {
	UNREACHABLE();
	return false;
	}
	}

	void DebugPrint() {
	for (intptr_t i = 0; i < kNumberOfCpuRegisters; i++) {
	Register r = static_cast<Register>(i);
	if (ContainsRegister(r)) {
	OS::Print("%s %s\n", Assembler::RegisterName(r),
	IsTagged(r) ? "tagged" : "untagged");
	}
	}

	for (intptr_t i = 0; i < kNumberOfFpuRegisters; i++) {
	FpuRegister r = static_cast<FpuRegister>(i);
	if (ContainsFpuRegister(r)) {
	OS::Print("%s\n", Assembler::FpuRegisterName(r));
	}
	}
	}

	void MarkUntagged(Location loc) {
	ASSERT(loc.IsRegister());
	untagged_cpu_registers_ \|= (1 << loc.reg());
	}

	bool IsTagged(Register reg) const {
	return (untagged_cpu_registers_ & (1 << reg)) == 0;
	}

	bool ContainsRegister(Register reg) const {
	return Contains(cpu_registers_, reg);
	}

	bool ContainsFpuRegister(FpuRegister fpu_reg) const {
	return Contains(fpu_registers_, fpu_reg);
	}

	intptr_t CpuRegisterCount() const { return RegisterCount(cpu_registers_); }
	intptr_t FpuRegisterCount() const { return RegisterCount(fpu_registers_); }

	static intptr_t RegisterCount(intptr_t registers);
	static bool Contains(intptr_t register_set, intptr_t reg) {
	return (register_set & (1 << reg)) != 0;
	}

	intptr_t cpu_registers() const { return cpu_registers_; }
	intptr_t fpu_registers() const { return fpu_registers_; }

	private:
	intptr_t cpu_registers_;
	intptr_t untagged_cpu_registers_;
	intptr_t fpu_registers_;

	DISALLOW_COPY_AND_ASSIGN(RegisterSet);
	};


	// Specification of locations for inputs and output.
	class LocationSummary : public ZoneAllocated {
	public:
	enum ContainsCall {
	kNoCall,
	kCall,
	kCallOnSlowPath
	};

	LocationSummary(Isolate* isolate,
	intptr_t input_count,
	intptr_t temp_count,
	LocationSummary::ContainsCall contains_call);

	intptr_t input_count() const {
	return num_inputs_;
	}

	Location in(intptr_t index) const {
	ASSERT(index >= 0);
	ASSERT(index < num_inputs_);
	return input_locations_[index];
	}

	Location* in_slot(intptr_t index) {
	ASSERT(index >= 0);
	ASSERT(index < num_inputs_);
	return &input_locations_[index];
	}

	void set_in(intptr_t index, Location loc) {
	ASSERT(index >= 0);
	ASSERT(index < num_inputs_);
	ASSERT(!always_calls() \|\| loc.IsMachineRegister());
	input_locations_[index] = loc;
	}

	intptr_t temp_count() const {
	return num_temps_;
	}

	Location temp(intptr_t index) const {
	ASSERT(index >= 0);
	ASSERT(index < num_temps_);
	return temp_locations_[index];
	}

	Location* temp_slot(intptr_t index) {
	ASSERT(index >= 0);
	ASSERT(index < num_temps_);
	return &temp_locations_[index];
	}

	void set_temp(intptr_t index, Location loc) {
	ASSERT(index >= 0);
	ASSERT(index < num_temps_);
	ASSERT(!always_calls() \|\| loc.IsMachineRegister());
	temp_locations_[index] = loc;
	}

	intptr_t output_count() const {
	return 1;
	}

	Location out(intptr_t index) const {
	ASSERT(index == 0);
	return output_location_;
	}

	Location* out_slot(intptr_t index) {
	ASSERT(index == 0);
	return &output_location_;
	}

	void set_out(intptr_t index, Location loc) {
	ASSERT(index == 0);
	ASSERT(!always_calls() \|\|
	(loc.IsMachineRegister() \|\| loc.IsInvalid() \|\|
	loc.IsPairLocation()));
	output_location_ = loc;
	}

	BitmapBuilder* stack_bitmap() {
	if (stack_bitmap_ == NULL) {
	stack_bitmap_ = new BitmapBuilder();
	}
	return stack_bitmap_;
	}
	void SetStackBit(intptr_t index) {
	stack_bitmap()->Set(index, true);
	}

	bool always_calls() const {
	return contains_call_ == kCall;
	}

	bool can_call() {
	return contains_call_ != kNoCall;
	}

	bool HasCallOnSlowPath() {
	return can_call() && !always_calls();
	}

	void PrintTo(BufferFormatter* f) const;

	static LocationSummary* Make(Isolate* isolate,
	intptr_t input_count,
	Location out,
	ContainsCall contains_call);

	RegisterSet* live_registers() {
	return &live_registers_;
	}

	#if defined(DEBUG)
	// Debug only verification that ensures that writable registers are correctly
	// preserved on the slow path.
	void DiscoverWritableInputs();
	void CheckWritableInputs();
	#endif

	private:
	const intptr_t num_inputs_;
	Location* input_locations_;
	const intptr_t num_temps_;
	Location* temp_locations_;
	Location output_location_;

	BitmapBuilder* stack_bitmap_;

	const ContainsCall contains_call_;
	RegisterSet live_registers_;

	#if defined(DEBUG)
	intptr_t writable_inputs_;
	#endif
	};


	} // namespace dart

	#endif // VM_LOCATIONS_H_