src/compiler/types.h - v8/v8 - Git at Google

 // Copyright 2014 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_COMPILER_TYPES_H_
 #define V8_COMPILER_TYPES_H_

 #include "src/base/compiler-specific.h"
 #include "src/common/globals.h"
 #include "src/compiler/heap-refs.h"
 #include "src/handles/handles.h"
 #include "src/numbers/conversions.h"
 #include "src/objects/objects.h"
 #include "src/utils/ostreams.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 // SUMMARY
 //
 // A simple type system for compiler-internal use. It is based entirely on
 // union types, and all subtyping hence amounts to set inclusion. Besides the
 // obvious primitive types and some predefined unions, the type language also
 // can express class types (a.k.a. specific maps) and singleton types (i.e.,
 // concrete constants).
 //
 // The following equations and inequations hold:
 //
 //   None <= T
 //   T <= Any
 //
 //   Number = Signed32 \/ Unsigned32 \/ Double
 //   Smi <= Signed32
 //   Name = String \/ Symbol
 //   UniqueName = InternalizedString \/ Symbol
 //   InternalizedString < String
 //
 //   Receiver = Object \/ Proxy
 //   OtherUndetectable < Object
 //   DetectableReceiver = Receiver - OtherUndetectable
 //
 //   Constant(x) < T  iff instance_type(map(x)) < T
 //
 //
 // RANGE TYPES
 //
 // A range type represents a continuous integer interval by its minimum and
 // maximum value.  Either value may be an infinity, in which case that infinity
 // itself is also included in the range.   A range never contains NaN or -0.
 //
 // If a value v happens to be an integer n, then Constant(v) is considered a
 // subtype of Range(n, n) (and therefore also a subtype of any larger range).
 // In order to avoid large unions, however, it is usually a good idea to use
 // Range rather than Constant.
 //
 //
 // PREDICATES
 //
 // There are two main functions for testing types:
 //
 //   T1.Is(T2)     -- tests whether T1 is included in T2 (i.e., T1 <= T2)
 //   T1.Maybe(T2)  -- tests whether T1 and T2 overlap (i.e., T1 /\ T2 =/= 0)
 //
 // Typically, the former is to be used to select representations (e.g., via
 // T.Is(SignedSmall())), and the latter to check whether a specific case needs
 // handling (e.g., via T.Maybe(Number())).
 //
 // There is no functionality to discover whether a type is a leaf in the
 // lattice. That is intentional. It should always be possible to refine the
 // lattice (e.g., splitting up number types further) without invalidating any
 // existing assumptions or tests.
 // Consequently, do not normally use Equals for type tests, always use Is!
 //
 // The NowIs operator implements state-sensitive subtying, as described above.
 // Any compilation decision based on such temporary properties requires runtime
 // guarding!
 //
 //
 // PROPERTIES
 //
 // Various formal properties hold for constructors, operators, and predicates
 // over types. For example, constructors are injective and subtyping is a
 // complete partial order.
 //
 // See test/cctest/test-types.cc for a comprehensive executable specification,
 // especially with respect to the properties of the more exotic 'temporal'
 // constructors and predicates (those prefixed 'Now').
 //
 //
 // IMPLEMENTATION
 //
 // Internally, all 'primitive' types, and their unions, are represented as
 // bitsets. Bit 0 is reserved for tagging. Only structured types require
 // allocation.

 // -----------------------------------------------------------------------------
 // Values for bitset types

 // clang-format off

 #define INTERNAL_BITSET_TYPE_LIST(V)                                      \
   V(OtherUnsigned31, 1u << 1)  \
   V(OtherUnsigned32, 1u << 2)  \
   V(OtherSigned32,   1u << 3)  \
   V(OtherNumber,     1u << 4)  \
   V(OtherString,     1u << 5)  \

 #define PROPER_BITSET_TYPE_LIST(V) \
   V(None,                     0u)        \
   V(Negative31,               1u << 6)   \
   V(Null,                     1u << 7)   \
   V(Undefined,                1u << 8)   \
   V(Boolean,                  1u << 9)   \
   V(Unsigned30,               1u << 10)  \
   V(MinusZero,                1u << 11)  \
   V(NaN,                      1u << 12)  \
   V(Symbol,                   1u << 13)  \
   V(InternalizedString,       1u << 14)  \
   V(OtherCallable,            1u << 16)  \
   V(OtherObject,              1u << 17)  \
   V(OtherUndetectable,        1u << 18)  \
   V(CallableProxy,            1u << 19)  \
   V(OtherProxy,               1u << 20)  \
   V(Function,                 1u << 21)  \
   V(BoundFunction,            1u << 22)  \
   V(Hole,                     1u << 23)  \
   V(OtherInternal,            1u << 24)  \
   V(ExternalPointer,          1u << 25)  \
   V(Array,                    1u << 26)  \
   V(BigInt,                   1u << 27)  \
   /* TODO(v8:10391): Remove this type once all ExternalPointer usages are */ \
   /* sandbox-ready. */                   \
   V(SandboxedExternalPointer, 1u << 28)  \
   \
   V(Signed31,                     kUnsigned30 | kNegative31) \
   V(Signed32,                     kSigned31 | kOtherUnsigned31 | \
                                   kOtherSigned32) \
   V(Signed32OrMinusZero,          kSigned32 | kMinusZero) \
   V(Signed32OrMinusZeroOrNaN,     kSigned32 | kMinusZero | kNaN) \
   V(Negative32,                   kNegative31 | kOtherSigned32) \
   V(Unsigned31,                   kUnsigned30 | kOtherUnsigned31) \
   V(Unsigned32,                   kUnsigned30 | kOtherUnsigned31 | \
                                   kOtherUnsigned32) \
   V(Unsigned32OrMinusZero,        kUnsigned32 | kMinusZero) \
   V(Unsigned32OrMinusZeroOrNaN,   kUnsigned32 | kMinusZero | kNaN) \
   V(Integral32,                   kSigned32 | kUnsigned32) \
   V(Integral32OrMinusZero,        kIntegral32 | kMinusZero) \
   V(Integral32OrMinusZeroOrNaN,   kIntegral32OrMinusZero | kNaN) \
   V(PlainNumber,                  kIntegral32 | kOtherNumber) \
   V(OrderedNumber,                kPlainNumber | kMinusZero) \
   V(MinusZeroOrNaN,               kMinusZero | kNaN) \
   V(Number,                       kOrderedNumber | kNaN) \
   V(Numeric,                      kNumber | kBigInt) \
   V(String,                       kInternalizedString | kOtherString) \
   V(UniqueName,                   kSymbol | kInternalizedString) \
   V(Name,                         kSymbol | kString) \
   V(InternalizedStringOrNull,     kInternalizedString | kNull) \
   V(BooleanOrNumber,              kBoolean | kNumber) \
   V(BooleanOrNullOrNumber,        kBooleanOrNumber | kNull) \
   V(BooleanOrNullOrUndefined,     kBoolean | kNull | kUndefined) \
   V(Oddball,                      kBooleanOrNullOrUndefined | kHole) \
   V(NullOrNumber,                 kNull | kNumber) \
   V(NullOrUndefined,              kNull | kUndefined) \
   V(Undetectable,                 kNullOrUndefined | kOtherUndetectable) \
   V(NumberOrHole,                 kNumber | kHole) \
   V(NumberOrOddball,              kNumber | kNullOrUndefined | kBoolean | \
                                   kHole) \
   V(NumericOrString,              kNumeric | kString) \
   V(NumberOrUndefined,            kNumber | kUndefined) \
   V(NumberOrUndefinedOrNullOrBoolean,  \
                                   kNumber | kNullOrUndefined | kBoolean) \
   V(PlainPrimitive,               kNumber | kString | kBoolean | \
                                   kNullOrUndefined) \
   V(NonBigIntPrimitive,           kSymbol | kPlainPrimitive) \
   V(Primitive,                    kBigInt | kNonBigIntPrimitive) \
   V(OtherUndetectableOrUndefined, kOtherUndetectable | kUndefined) \
   V(Proxy,                        kCallableProxy | kOtherProxy) \
   V(ArrayOrOtherObject,           kArray | kOtherObject) \
   V(ArrayOrProxy,                 kArray | kProxy) \
   V(DetectableCallable,           kFunction | kBoundFunction | \
                                   kOtherCallable | kCallableProxy) \
   V(Callable,                     kDetectableCallable | kOtherUndetectable) \
   V(NonCallable,                  kArray | kOtherObject | kOtherProxy) \
   V(NonCallableOrNull,            kNonCallable | kNull) \
   V(DetectableObject,             kArray | kFunction | kBoundFunction | \
                                   kOtherCallable | kOtherObject) \
   V(DetectableReceiver,           kDetectableObject | kProxy) \
   V(DetectableReceiverOrNull,     kDetectableReceiver | kNull) \
   V(Object,                       kDetectableObject | kOtherUndetectable) \
   V(Receiver,                     kObject | kProxy) \
   V(ReceiverOrUndefined,          kReceiver | kUndefined) \
   V(ReceiverOrNullOrUndefined,    kReceiver | kNull | kUndefined) \
   V(SymbolOrReceiver,             kSymbol | kReceiver) \
   V(StringOrReceiver,             kString | kReceiver) \
   V(Unique,                       kBoolean | kUniqueName | kNull | \
                                   kUndefined | kHole | kReceiver) \
   V(Internal,                     kHole | kExternalPointer | \
                                   kSandboxedExternalPointer | kOtherInternal) \
   V(NonInternal,                  kPrimitive | kReceiver) \
   V(NonBigInt,                    kNonBigIntPrimitive | kReceiver) \
   V(NonNumber,                    kBigInt | kUnique | kString | kInternal) \
   V(Any,                          0xfffffffeu)

 // clang-format on

 /*
  * The following diagrams show how integers (in the mathematical sense) are
  * divided among the different atomic numerical types.
  *
  *   ON    OS32     N31     U30     OU31    OU32     ON
  * ______[_______[_______[_______[_______[_______[_______
  *     -2^31   -2^30     0      2^30    2^31    2^32
  *
  * E.g., OtherUnsigned32 (OU32) covers all integers from 2^31 to 2^32-1.
  *
  * Some of the atomic numerical bitsets are internal only (see
  * INTERNAL_BITSET_TYPE_LIST).  To a types user, they should only occur in
  * union with certain other bitsets.  For instance, OtherNumber should only
  * occur as part of PlainNumber.
  */

 #define BITSET_TYPE_LIST(V)    \
   INTERNAL_BITSET_TYPE_LIST(V) \
   PROPER_BITSET_TYPE_LIST(V)

 class JSHeapBroker;
 class HeapConstantType;
 class OtherNumberConstantType;
 class TupleType;
 class Type;
 class UnionType;

 // -----------------------------------------------------------------------------
 // Bitset types (internal).

 class V8_EXPORT_PRIVATE BitsetType {
  public:
   using bitset = uint32_t;  // Internal

   enum : uint32_t {
 #define DECLARE_TYPE(type, value) k##type = (value),
     BITSET_TYPE_LIST(DECLARE_TYPE)
 #undef DECLARE_TYPE
         kUnusedEOL = 0
   };

   static bitset SignedSmall();
   static bitset UnsignedSmall();

   static bool IsNone(bitset bits) { return bits == kNone; }

   static bool Is(bitset bits1, bitset bits2) {
     return (bits1 | bits2) == bits2;
   }

   static double Min(bitset);
   static double Max(bitset);

   static bitset Glb(double min, double max);
   static bitset Lub(HeapObjectType const& type) {
     return Lub<HeapObjectType>(type);
   }
   static bitset Lub(MapRef const& map) { return Lub<MapRef>(map); }
   static bitset Lub(double value);
   static bitset Lub(double min, double max);
   static bitset ExpandInternals(bitset bits);

   static const char* Name(bitset);
   static void Print(std::ostream& os, bitset);  // NOLINT
 #ifdef DEBUG
   static void Print(bitset);
 #endif

   static bitset NumberBits(bitset bits);

  private:
   struct Boundary {
     bitset internal;
     bitset external;
     double min;
   };
   static const Boundary BoundariesArray[];
   static inline const Boundary* Boundaries();
   static inline size_t BoundariesSize();

   template <typename MapRefLike>
   static bitset Lub(MapRefLike const& map);
 };

 // -----------------------------------------------------------------------------
 // Superclass for non-bitset types (internal).
 class TypeBase {
  protected:
   friend class Type;

   enum Kind { kHeapConstant, kOtherNumberConstant, kTuple, kUnion, kRange };

   Kind kind() const { return kind_; }
   explicit TypeBase(Kind kind) : kind_(kind) {}

   static bool IsKind(Type type, Kind kind);

  private:
   Kind kind_;
 };

 // -----------------------------------------------------------------------------
 // Range types.

 class RangeType : public TypeBase {
  public:
   struct Limits {
     double min;
     double max;
     Limits(double min, double max) : min(min), max(max) {}
     explicit Limits(const RangeType* range)
         : min(range->Min()), max(range->Max()) {}
     bool IsEmpty();
     static Limits Empty() { return Limits(1, 0); }
     static Limits Intersect(Limits lhs, Limits rhs);
     static Limits Union(Limits lhs, Limits rhs);
   };

   double Min() const { return limits_.min; }
   double Max() const { return limits_.max; }

   static bool IsInteger(double x) {
     return nearbyint(x) == x && !IsMinusZero(x);  // Allows for infinities.
   }

  private:
   friend class Type;
   friend class BitsetType;
   friend class UnionType;
   friend Zone;

   static RangeType* New(double min, double max, Zone* zone) {
     return New(Limits(min, max), zone);
   }

   static RangeType* New(Limits lim, Zone* zone) {
     DCHECK(IsInteger(lim.min) && IsInteger(lim.max));
     DCHECK(lim.min <= lim.max);
     BitsetType::bitset bits = BitsetType::Lub(lim.min, lim.max);

     return zone->New<RangeType>(bits, lim);
   }

   RangeType(BitsetType::bitset bitset, Limits limits)
       : TypeBase(kRange), bitset_(bitset), limits_(limits) {}

   BitsetType::bitset Lub() const { return bitset_; }

   BitsetType::bitset bitset_;
   Limits limits_;
 };

 // -----------------------------------------------------------------------------
 // The actual type.

 class V8_EXPORT_PRIVATE Type {
  public:
   using bitset = BitsetType::bitset;  // Internal

 // Constructors.
 #define DEFINE_TYPE_CONSTRUCTOR(type, value) \
   static Type type() { return NewBitset(BitsetType::k##type); }
   PROPER_BITSET_TYPE_LIST(DEFINE_TYPE_CONSTRUCTOR)
 #undef DEFINE_TYPE_CONSTRUCTOR

   Type() : payload_(0) {}

   static Type SignedSmall() { return NewBitset(BitsetType::SignedSmall()); }
   static Type UnsignedSmall() { return NewBitset(BitsetType::UnsignedSmall()); }

   static Type Constant(JSHeapBroker* broker, Handle<i::Object> value,
                        Zone* zone);
   static Type Constant(double value, Zone* zone);
   static Type Range(double min, double max, Zone* zone);
   static Type Tuple(Type first, Type second, Type third, Zone* zone);

   static Type Union(Type type1, Type type2, Zone* zone);
   static Type Intersect(Type type1, Type type2, Zone* zone);

   static Type For(MapRef const& type) {
     return NewBitset(BitsetType::ExpandInternals(BitsetType::Lub(type)));
   }

   // Predicates.
   bool IsNone() const { return payload_ == None().payload_; }
   bool IsInvalid() const { return payload_ == 0u; }

   bool Is(Type that) const {
     return payload_ == that.payload_ || this->SlowIs(that);
   }
   bool Maybe(Type that) const;
   bool Equals(Type that) const { return this->Is(that) && that.Is(*this); }

   // Inspection.
   bool IsBitset() const { return payload_ & 1; }
   bool IsRange() const { return IsKind(TypeBase::kRange); }
   bool IsHeapConstant() const { return IsKind(TypeBase::kHeapConstant); }
   bool IsOtherNumberConstant() const {
     return IsKind(TypeBase::kOtherNumberConstant);
   }
   bool IsTuple() const { return IsKind(TypeBase::kTuple); }

   bool IsSingleton() const {
     if (IsNone()) return false;
     return Is(Type::Null()) || Is(Type::Undefined()) || Is(Type::MinusZero()) ||
            Is(Type::NaN()) || Is(Type::Hole()) || IsHeapConstant() ||
            (Is(Type::PlainNumber()) && Min() == Max());
   }

   const HeapConstantType* AsHeapConstant() const;
   const OtherNumberConstantType* AsOtherNumberConstant() const;
   const RangeType* AsRange() const;
   const TupleType* AsTuple() const;

   // Minimum and maximum of a numeric type.
   // These functions do not distinguish between -0 and +0.  NaN is ignored.
   // Only call them on subtypes of Number whose intersection with OrderedNumber
   // is not empty.
   double Min() const;
   double Max() const;

   // Extracts a range from the type: if the type is a range or a union
   // containing a range, that range is returned; otherwise, nullptr is returned.
   Type GetRange() const;

   int NumConstants() const;

   static Type Invalid() { return Type(); }

   bool operator==(Type other) const { return payload_ == other.payload_; }
   bool operator!=(Type other) const { return payload_ != other.payload_; }

   // Printing.

   void PrintTo(std::ostream& os) const;

 #ifdef DEBUG
   void Print() const;
 #endif

   // Helpers for testing.
   bool IsUnionForTesting() { return IsUnion(); }
   bitset AsBitsetForTesting() { return AsBitset(); }
   const UnionType* AsUnionForTesting() { return AsUnion(); }
   Type BitsetGlbForTesting() { return NewBitset(BitsetGlb()); }
   Type BitsetLubForTesting() { return NewBitset(BitsetLub()); }

  private:
   // Friends.
   template <class>
   friend class Iterator;
   friend BitsetType;
   friend UnionType;
   friend size_t hash_value(Type type);

   explicit Type(bitset bits) : payload_(bits | 1u) {}

   Type(TypeBase* type_base)  // NOLINT(runtime/explicit)
       : payload_(reinterpret_cast<uintptr_t>(type_base)) {}

   // Internal inspection.
   bool IsKind(TypeBase::Kind kind) const {
     if (IsBitset()) return false;
     const TypeBase* base = ToTypeBase();
     return base->kind() == kind;
   }

   const TypeBase* ToTypeBase() const {
     return reinterpret_cast<TypeBase*>(payload_);
   }
   static Type FromTypeBase(TypeBase* type) { return Type(type); }

   bool IsAny() const { return payload_ == Any().payload_; }
   bool IsUnion() const { return IsKind(TypeBase::kUnion); }

   bitset AsBitset() const {
     DCHECK(IsBitset());
     return static_cast<bitset>(payload_) ^ 1u;
   }

   const UnionType* AsUnion() const;

   bitset BitsetGlb() const;  // greatest lower bound that's a bitset
   bitset BitsetLub() const;  // least upper bound that's a bitset

   bool SlowIs(Type that) const;

   static Type NewBitset(bitset bits) { return Type(bits); }

   static Type Range(RangeType::Limits lims, Zone* zone);
   static Type OtherNumberConstant(double value, Zone* zone);
   static Type HeapConstant(const HeapObjectRef& value, Zone* zone);

   static bool Overlap(const RangeType* lhs, const RangeType* rhs);
   static bool Contains(const RangeType* lhs, const RangeType* rhs);

   static int UpdateRange(Type type, UnionType* result, int size, Zone* zone);

   static RangeType::Limits IntersectRangeAndBitset(Type range, Type bits,
                                                    Zone* zone);
   static RangeType::Limits ToLimits(bitset bits, Zone* zone);

   bool SimplyEquals(Type that) const;

   static int AddToUnion(Type type, UnionType* result, int size, Zone* zone);
   static int IntersectAux(Type type, Type other, UnionType* result, int size,
                           RangeType::Limits* limits, Zone* zone);
   static Type NormalizeUnion(UnionType* unioned, int size, Zone* zone);
   static Type NormalizeRangeAndBitset(Type range, bitset* bits, Zone* zone);

   // If LSB is set, the payload is a bitset; if LSB is clear, the payload is
   // a pointer to a subtype of the TypeBase class.
   uintptr_t payload_;
 };

 inline size_t hash_value(Type type) { return type.payload_; }
 V8_EXPORT_PRIVATE std::ostream& operator<<(std::ostream& os, Type type);

 // -----------------------------------------------------------------------------
 // Constant types.

 class OtherNumberConstantType : public TypeBase {
  public:
   double Value() const { return value_; }

   static bool IsOtherNumberConstant(double value);

  private:
   friend class Type;
   friend class BitsetType;
   friend Zone;

   static OtherNumberConstantType* New(double value, Zone* zone) {
     return zone->New<OtherNumberConstantType>(value);
   }

   explicit OtherNumberConstantType(double value)
       : TypeBase(kOtherNumberConstant), value_(value) {
     CHECK(IsOtherNumberConstant(value));
   }

   BitsetType::bitset Lub() const { return BitsetType::kOtherNumber; }

   double value_;
 };

 class V8_EXPORT_PRIVATE HeapConstantType : public NON_EXPORTED_BASE(TypeBase) {
  public:
   Handle<HeapObject> Value() const;
   const HeapObjectRef& Ref() const { return heap_ref_; }

  private:
   friend class Type;
   friend class BitsetType;
   friend Zone;

   static HeapConstantType* New(const HeapObjectRef& heap_ref,
                                BitsetType::bitset bitset, Zone* zone) {
     return zone->New<HeapConstantType>(bitset, heap_ref);
   }

   HeapConstantType(BitsetType::bitset bitset, const HeapObjectRef& heap_ref);

   BitsetType::bitset Lub() const { return bitset_; }

   BitsetType::bitset bitset_;
   HeapObjectRef heap_ref_;
 };

 // -----------------------------------------------------------------------------
 // Superclass for types with variable number of type fields.
 class StructuralType : public TypeBase {
  public:
   int LengthForTesting() const { return Length(); }

  protected:
   friend class Type;

   int Length() const { return length_; }

   Type Get(int i) const {
     DCHECK(0 <= i && i < this->Length());
     return elements_[i];
   }

   void Set(int i, Type type) {
     DCHECK(0 <= i && i < this->Length());
     elements_[i] = type;
   }

   void Shrink(int length) {
     DCHECK(2 <= length && length <= this->Length());
     length_ = length;
   }

   StructuralType(Kind kind, int length, Zone* zone)
       : TypeBase(kind), length_(length) {
     elements_ = zone->NewArray<Type>(length);
   }

  private:
   int length_;
   Type* elements_;
 };

 // -----------------------------------------------------------------------------
 // Tuple types.

 class TupleType : public StructuralType {
  public:
   int Arity() const { return this->Length(); }
   Type Element(int i) const { return this->Get(i); }

   void InitElement(int i, Type type) { this->Set(i, type); }

  private:
   friend Type;
   friend Zone;

   TupleType(int length, Zone* zone) : StructuralType(kTuple, length, zone) {}

   static TupleType* New(int length, Zone* zone) {
     return zone->New<TupleType>(length, zone);
   }
 };

 // -----------------------------------------------------------------------------
 // Union types (internal).
 // A union is a structured type with the following invariants:
 // - its length is at least 2
 // - at most one field is a bitset, and it must go into index 0
 // - no field is a union
 // - no field is a subtype of any other field
 class UnionType : public StructuralType {
  private:
   friend Type;
   friend BitsetType;
   friend Zone;

   UnionType(int length, Zone* zone) : StructuralType(kUnion, length, zone) {}

   static UnionType* New(int length, Zone* zone) {
     return zone->New<UnionType>(length, zone);
   }

   bool Wellformed() const;
 };

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_COMPILER_TYPES_H_
	// Copyright 2014 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_COMPILER_TYPES_H_
	#define V8_COMPILER_TYPES_H_

	#include "src/base/compiler-specific.h"
	#include "src/common/globals.h"
	#include "src/compiler/heap-refs.h"
	#include "src/handles/handles.h"
	#include "src/numbers/conversions.h"
	#include "src/objects/objects.h"
	#include "src/utils/ostreams.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	// SUMMARY
	//
	// A simple type system for compiler-internal use. It is based entirely on
	// union types, and all subtyping hence amounts to set inclusion. Besides the
	// obvious primitive types and some predefined unions, the type language also
	// can express class types (a.k.a. specific maps) and singleton types (i.e.,
	// concrete constants).
	//
	// The following equations and inequations hold:
	//
	// None <= T
	// T <= Any
	//
	// Number = Signed32 \/ Unsigned32 \/ Double
	// Smi <= Signed32
	// Name = String \/ Symbol
	// UniqueName = InternalizedString \/ Symbol
	// InternalizedString < String
	//
	// Receiver = Object \/ Proxy
	// OtherUndetectable < Object
	// DetectableReceiver = Receiver - OtherUndetectable
	//
	// Constant(x) < T iff instance_type(map(x)) < T
	//
	//
	// RANGE TYPES
	//
	// A range type represents a continuous integer interval by its minimum and
	// maximum value. Either value may be an infinity, in which case that infinity
	// itself is also included in the range. A range never contains NaN or -0.
	//
	// If a value v happens to be an integer n, then Constant(v) is considered a
	// subtype of Range(n, n) (and therefore also a subtype of any larger range).
	// In order to avoid large unions, however, it is usually a good idea to use
	// Range rather than Constant.
	//
	//
	// PREDICATES
	//
	// There are two main functions for testing types:
	//
	// T1.Is(T2) -- tests whether T1 is included in T2 (i.e., T1 <= T2)
	// T1.Maybe(T2) -- tests whether T1 and T2 overlap (i.e., T1 /\ T2 =/= 0)
	//
	// Typically, the former is to be used to select representations (e.g., via
	// T.Is(SignedSmall())), and the latter to check whether a specific case needs
	// handling (e.g., via T.Maybe(Number())).
	//
	// There is no functionality to discover whether a type is a leaf in the
	// lattice. That is intentional. It should always be possible to refine the
	// lattice (e.g., splitting up number types further) without invalidating any
	// existing assumptions or tests.
	// Consequently, do not normally use Equals for type tests, always use Is!
	//
	// The NowIs operator implements state-sensitive subtying, as described above.
	// Any compilation decision based on such temporary properties requires runtime
	// guarding!
	//
	//
	// PROPERTIES
	//
	// Various formal properties hold for constructors, operators, and predicates
	// over types. For example, constructors are injective and subtyping is a
	// complete partial order.
	//
	// See test/cctest/test-types.cc for a comprehensive executable specification,
	// especially with respect to the properties of the more exotic 'temporal'
	// constructors and predicates (those prefixed 'Now').
	//
	//
	// IMPLEMENTATION
	//
	// Internally, all 'primitive' types, and their unions, are represented as
	// bitsets. Bit 0 is reserved for tagging. Only structured types require
	// allocation.

	// -----------------------------------------------------------------------------
	// Values for bitset types

	// clang-format off

	#define INTERNAL_BITSET_TYPE_LIST(V) \
	V(OtherUnsigned31, 1u << 1) \
	V(OtherUnsigned32, 1u << 2) \
	V(OtherSigned32, 1u << 3) \
	V(OtherNumber, 1u << 4) \
	V(OtherString, 1u << 5) \

	#define PROPER_BITSET_TYPE_LIST(V) \
	V(None, 0u) \
	V(Negative31, 1u << 6) \
	V(Null, 1u << 7) \
	V(Undefined, 1u << 8) \
	V(Boolean, 1u << 9) \
	V(Unsigned30, 1u << 10) \
	V(MinusZero, 1u << 11) \
	V(NaN, 1u << 12) \
	V(Symbol, 1u << 13) \
	V(InternalizedString, 1u << 14) \
	V(OtherCallable, 1u << 16) \
	V(OtherObject, 1u << 17) \
	V(OtherUndetectable, 1u << 18) \
	V(CallableProxy, 1u << 19) \
	V(OtherProxy, 1u << 20) \
	V(Function, 1u << 21) \
	V(BoundFunction, 1u << 22) \
	V(Hole, 1u << 23) \
	V(OtherInternal, 1u << 24) \
	V(ExternalPointer, 1u << 25) \
	V(Array, 1u << 26) \
	V(BigInt, 1u << 27) \
	/* TODO(v8:10391): Remove this type once all ExternalPointer usages are */ \
	/* sandbox-ready. */ \
	V(SandboxedExternalPointer, 1u << 28) \
	\
	V(Signed31, kUnsigned30 \| kNegative31) \
	V(Signed32, kSigned31 \| kOtherUnsigned31 \| \
	kOtherSigned32) \
	V(Signed32OrMinusZero, kSigned32 \| kMinusZero) \
	V(Signed32OrMinusZeroOrNaN, kSigned32 \| kMinusZero \| kNaN) \
	V(Negative32, kNegative31 \| kOtherSigned32) \
	V(Unsigned31, kUnsigned30 \| kOtherUnsigned31) \
	V(Unsigned32, kUnsigned30 \| kOtherUnsigned31 \| \
	kOtherUnsigned32) \
	V(Unsigned32OrMinusZero, kUnsigned32 \| kMinusZero) \
	V(Unsigned32OrMinusZeroOrNaN, kUnsigned32 \| kMinusZero \| kNaN) \
	V(Integral32, kSigned32 \| kUnsigned32) \
	V(Integral32OrMinusZero, kIntegral32 \| kMinusZero) \
	V(Integral32OrMinusZeroOrNaN, kIntegral32OrMinusZero \| kNaN) \
	V(PlainNumber, kIntegral32 \| kOtherNumber) \
	V(OrderedNumber, kPlainNumber \| kMinusZero) \
	V(MinusZeroOrNaN, kMinusZero \| kNaN) \
	V(Number, kOrderedNumber \| kNaN) \
	V(Numeric, kNumber \| kBigInt) \
	V(String, kInternalizedString \| kOtherString) \
	V(UniqueName, kSymbol \| kInternalizedString) \
	V(Name, kSymbol \| kString) \
	V(InternalizedStringOrNull, kInternalizedString \| kNull) \
	V(BooleanOrNumber, kBoolean \| kNumber) \
	V(BooleanOrNullOrNumber, kBooleanOrNumber \| kNull) \
	V(BooleanOrNullOrUndefined, kBoolean \| kNull \| kUndefined) \
	V(Oddball, kBooleanOrNullOrUndefined \| kHole) \
	V(NullOrNumber, kNull \| kNumber) \
	V(NullOrUndefined, kNull \| kUndefined) \
	V(Undetectable, kNullOrUndefined \| kOtherUndetectable) \
	V(NumberOrHole, kNumber \| kHole) \
	V(NumberOrOddball, kNumber \| kNullOrUndefined \| kBoolean \| \
	kHole) \
	V(NumericOrString, kNumeric \| kString) \
	V(NumberOrUndefined, kNumber \| kUndefined) \
	V(NumberOrUndefinedOrNullOrBoolean, \
	kNumber \| kNullOrUndefined \| kBoolean) \
	V(PlainPrimitive, kNumber \| kString \| kBoolean \| \
	kNullOrUndefined) \
	V(NonBigIntPrimitive, kSymbol \| kPlainPrimitive) \
	V(Primitive, kBigInt \| kNonBigIntPrimitive) \
	V(OtherUndetectableOrUndefined, kOtherUndetectable \| kUndefined) \
	V(Proxy, kCallableProxy \| kOtherProxy) \
	V(ArrayOrOtherObject, kArray \| kOtherObject) \
	V(ArrayOrProxy, kArray \| kProxy) \
	V(DetectableCallable, kFunction \| kBoundFunction \| \
	kOtherCallable \| kCallableProxy) \
	V(Callable, kDetectableCallable \| kOtherUndetectable) \
	V(NonCallable, kArray \| kOtherObject \| kOtherProxy) \
	V(NonCallableOrNull, kNonCallable \| kNull) \
	V(DetectableObject, kArray \| kFunction \| kBoundFunction \| \
	kOtherCallable \| kOtherObject) \
	V(DetectableReceiver, kDetectableObject \| kProxy) \
	V(DetectableReceiverOrNull, kDetectableReceiver \| kNull) \
	V(Object, kDetectableObject \| kOtherUndetectable) \
	V(Receiver, kObject \| kProxy) \
	V(ReceiverOrUndefined, kReceiver \| kUndefined) \
	V(ReceiverOrNullOrUndefined, kReceiver \| kNull \| kUndefined) \
	V(SymbolOrReceiver, kSymbol \| kReceiver) \
	V(StringOrReceiver, kString \| kReceiver) \
	V(Unique, kBoolean \| kUniqueName \| kNull \| \
	kUndefined \| kHole \| kReceiver) \
	V(Internal, kHole \| kExternalPointer \| \
	kSandboxedExternalPointer \| kOtherInternal) \
	V(NonInternal, kPrimitive \| kReceiver) \
	V(NonBigInt, kNonBigIntPrimitive \| kReceiver) \
	V(NonNumber, kBigInt \| kUnique \| kString \| kInternal) \
	V(Any, 0xfffffffeu)

	// clang-format on

	/*
	* The following diagrams show how integers (in the mathematical sense) are
	* divided among the different atomic numerical types.
	*
	* ON OS32 N31 U30 OU31 OU32 ON
	* ______[_______[_______[_______[_______[_______[_______
	* -2^31 -2^30 0 2^30 2^31 2^32
	*
	* E.g., OtherUnsigned32 (OU32) covers all integers from 2^31 to 2^32-1.
	*
	* Some of the atomic numerical bitsets are internal only (see
	* INTERNAL_BITSET_TYPE_LIST). To a types user, they should only occur in
	* union with certain other bitsets. For instance, OtherNumber should only
	* occur as part of PlainNumber.
	*/

	#define BITSET_TYPE_LIST(V) \
	INTERNAL_BITSET_TYPE_LIST(V) \
	PROPER_BITSET_TYPE_LIST(V)

	class JSHeapBroker;
	class HeapConstantType;
	class OtherNumberConstantType;
	class TupleType;
	class Type;
	class UnionType;

	// -----------------------------------------------------------------------------
	// Bitset types (internal).

	class V8_EXPORT_PRIVATE BitsetType {
	public:
	using bitset = uint32_t; // Internal

	enum : uint32_t {
	#define DECLARE_TYPE(type, value) k##type = (value),
	BITSET_TYPE_LIST(DECLARE_TYPE)
	#undef DECLARE_TYPE
	kUnusedEOL = 0
	};

	static bitset SignedSmall();
	static bitset UnsignedSmall();

	static bool IsNone(bitset bits) { return bits == kNone; }

	static bool Is(bitset bits1, bitset bits2) {
	return (bits1 \| bits2) == bits2;
	}

	static double Min(bitset);
	static double Max(bitset);

	static bitset Glb(double min, double max);
	static bitset Lub(HeapObjectType const& type) {
	return Lub<HeapObjectType>(type);
	}
	static bitset Lub(MapRef const& map) { return Lub<MapRef>(map); }
	static bitset Lub(double value);
	static bitset Lub(double min, double max);
	static bitset ExpandInternals(bitset bits);

	static const char* Name(bitset);
	static void Print(std::ostream& os, bitset); // NOLINT
	#ifdef DEBUG
	static void Print(bitset);
	#endif

	static bitset NumberBits(bitset bits);

	private:
	struct Boundary {
	bitset internal;
	bitset external;
	double min;
	};
	static const Boundary BoundariesArray[];
	static inline const Boundary* Boundaries();
	static inline size_t BoundariesSize();

	template <typename MapRefLike>
	static bitset Lub(MapRefLike const& map);
	};

	// -----------------------------------------------------------------------------
	// Superclass for non-bitset types (internal).
	class TypeBase {
	protected:
	friend class Type;

	enum Kind { kHeapConstant, kOtherNumberConstant, kTuple, kUnion, kRange };

	Kind kind() const { return kind_; }
	explicit TypeBase(Kind kind) : kind_(kind) {}

	static bool IsKind(Type type, Kind kind);

	private:
	Kind kind_;
	};

	// -----------------------------------------------------------------------------
	// Range types.

	class RangeType : public TypeBase {
	public:
	struct Limits {
	double min;
	double max;
	Limits(double min, double max) : min(min), max(max) {}
	explicit Limits(const RangeType* range)
	: min(range->Min()), max(range->Max()) {}
	bool IsEmpty();
	static Limits Empty() { return Limits(1, 0); }
	static Limits Intersect(Limits lhs, Limits rhs);
	static Limits Union(Limits lhs, Limits rhs);
	};

	double Min() const { return limits_.min; }
	double Max() const { return limits_.max; }

	static bool IsInteger(double x) {
	return nearbyint(x) == x && !IsMinusZero(x); // Allows for infinities.
	}

	private:
	friend class Type;
	friend class BitsetType;
	friend class UnionType;
	friend Zone;

	static RangeType* New(double min, double max, Zone* zone) {
	return New(Limits(min, max), zone);
	}

	static RangeType* New(Limits lim, Zone* zone) {
	DCHECK(IsInteger(lim.min) && IsInteger(lim.max));
	DCHECK(lim.min <= lim.max);
	BitsetType::bitset bits = BitsetType::Lub(lim.min, lim.max);

	return zone->New<RangeType>(bits, lim);
	}

	RangeType(BitsetType::bitset bitset, Limits limits)
	: TypeBase(kRange), bitset_(bitset), limits_(limits) {}

	BitsetType::bitset Lub() const { return bitset_; }

	BitsetType::bitset bitset_;
	Limits limits_;
	};

	// -----------------------------------------------------------------------------
	// The actual type.

	class V8_EXPORT_PRIVATE Type {
	public:
	using bitset = BitsetType::bitset; // Internal

	// Constructors.
	#define DEFINE_TYPE_CONSTRUCTOR(type, value) \
	static Type type() { return NewBitset(BitsetType::k##type); }
	PROPER_BITSET_TYPE_LIST(DEFINE_TYPE_CONSTRUCTOR)
	#undef DEFINE_TYPE_CONSTRUCTOR

	Type() : payload_(0) {}

	static Type SignedSmall() { return NewBitset(BitsetType::SignedSmall()); }
	static Type UnsignedSmall() { return NewBitset(BitsetType::UnsignedSmall()); }

	static Type Constant(JSHeapBroker* broker, Handle<i::Object> value,
	Zone* zone);
	static Type Constant(double value, Zone* zone);
	static Type Range(double min, double max, Zone* zone);
	static Type Tuple(Type first, Type second, Type third, Zone* zone);

	static Type Union(Type type1, Type type2, Zone* zone);
	static Type Intersect(Type type1, Type type2, Zone* zone);

	static Type For(MapRef const& type) {
	return NewBitset(BitsetType::ExpandInternals(BitsetType::Lub(type)));
	}

	// Predicates.
	bool IsNone() const { return payload_ == None().payload_; }
	bool IsInvalid() const { return payload_ == 0u; }

	bool Is(Type that) const {
	return payload_ == that.payload_ \|\| this->SlowIs(that);
	}
	bool Maybe(Type that) const;
	bool Equals(Type that) const { return this->Is(that) && that.Is(*this); }

	// Inspection.
	bool IsBitset() const { return payload_ & 1; }
	bool IsRange() const { return IsKind(TypeBase::kRange); }
	bool IsHeapConstant() const { return IsKind(TypeBase::kHeapConstant); }
	bool IsOtherNumberConstant() const {
	return IsKind(TypeBase::kOtherNumberConstant);
	}
	bool IsTuple() const { return IsKind(TypeBase::kTuple); }

	bool IsSingleton() const {
	if (IsNone()) return false;
	return Is(Type::Null()) \|\| Is(Type::Undefined()) \|\| Is(Type::MinusZero()) \|\|
	Is(Type::NaN()) \|\| Is(Type::Hole()) \|\| IsHeapConstant() \|\|
	(Is(Type::PlainNumber()) && Min() == Max());
	}

	const HeapConstantType* AsHeapConstant() const;
	const OtherNumberConstantType* AsOtherNumberConstant() const;
	const RangeType* AsRange() const;
	const TupleType* AsTuple() const;

	// Minimum and maximum of a numeric type.
	// These functions do not distinguish between -0 and +0. NaN is ignored.
	// Only call them on subtypes of Number whose intersection with OrderedNumber
	// is not empty.
	double Min() const;
	double Max() const;

	// Extracts a range from the type: if the type is a range or a union
	// containing a range, that range is returned; otherwise, nullptr is returned.
	Type GetRange() const;

	int NumConstants() const;

	static Type Invalid() { return Type(); }

	bool operator==(Type other) const { return payload_ == other.payload_; }
	bool operator!=(Type other) const { return payload_ != other.payload_; }

	// Printing.

	void PrintTo(std::ostream& os) const;

	#ifdef DEBUG
	void Print() const;
	#endif

	// Helpers for testing.
	bool IsUnionForTesting() { return IsUnion(); }
	bitset AsBitsetForTesting() { return AsBitset(); }
	const UnionType* AsUnionForTesting() { return AsUnion(); }
	Type BitsetGlbForTesting() { return NewBitset(BitsetGlb()); }
	Type BitsetLubForTesting() { return NewBitset(BitsetLub()); }

	private:
	// Friends.
	template <class>
	friend class Iterator;
	friend BitsetType;
	friend UnionType;
	friend size_t hash_value(Type type);

	explicit Type(bitset bits) : payload_(bits \| 1u) {}

	Type(TypeBase* type_base) // NOLINT(runtime/explicit)
	: payload_(reinterpret_cast<uintptr_t>(type_base)) {}

	// Internal inspection.
	bool IsKind(TypeBase::Kind kind) const {
	if (IsBitset()) return false;
	const TypeBase* base = ToTypeBase();
	return base->kind() == kind;
	}

	const TypeBase* ToTypeBase() const {
	return reinterpret_cast<TypeBase*>(payload_);
	}
	static Type FromTypeBase(TypeBase* type) { return Type(type); }

	bool IsAny() const { return payload_ == Any().payload_; }
	bool IsUnion() const { return IsKind(TypeBase::kUnion); }

	bitset AsBitset() const {
	DCHECK(IsBitset());
	return static_cast<bitset>(payload_) ^ 1u;
	}

	const UnionType* AsUnion() const;

	bitset BitsetGlb() const; // greatest lower bound that's a bitset
	bitset BitsetLub() const; // least upper bound that's a bitset

	bool SlowIs(Type that) const;

	static Type NewBitset(bitset bits) { return Type(bits); }

	static Type Range(RangeType::Limits lims, Zone* zone);
	static Type OtherNumberConstant(double value, Zone* zone);
	static Type HeapConstant(const HeapObjectRef& value, Zone* zone);

	static bool Overlap(const RangeType* lhs, const RangeType* rhs);
	static bool Contains(const RangeType* lhs, const RangeType* rhs);

	static int UpdateRange(Type type, UnionType* result, int size, Zone* zone);

	static RangeType::Limits IntersectRangeAndBitset(Type range, Type bits,
	Zone* zone);
	static RangeType::Limits ToLimits(bitset bits, Zone* zone);

	bool SimplyEquals(Type that) const;

	static int AddToUnion(Type type, UnionType* result, int size, Zone* zone);
	static int IntersectAux(Type type, Type other, UnionType* result, int size,
	RangeType::Limits* limits, Zone* zone);
	static Type NormalizeUnion(UnionType* unioned, int size, Zone* zone);
	static Type NormalizeRangeAndBitset(Type range, bitset* bits, Zone* zone);

	// If LSB is set, the payload is a bitset; if LSB is clear, the payload is
	// a pointer to a subtype of the TypeBase class.
	uintptr_t payload_;
	};

	inline size_t hash_value(Type type) { return type.payload_; }
	V8_EXPORT_PRIVATE std::ostream& operator<<(std::ostream& os, Type type);

	// -----------------------------------------------------------------------------
	// Constant types.

	class OtherNumberConstantType : public TypeBase {
	public:
	double Value() const { return value_; }

	static bool IsOtherNumberConstant(double value);

	private:
	friend class Type;
	friend class BitsetType;
	friend Zone;

	static OtherNumberConstantType* New(double value, Zone* zone) {
	return zone->New<OtherNumberConstantType>(value);
	}

	explicit OtherNumberConstantType(double value)
	: TypeBase(kOtherNumberConstant), value_(value) {
	CHECK(IsOtherNumberConstant(value));
	}

	BitsetType::bitset Lub() const { return BitsetType::kOtherNumber; }

	double value_;
	};

	class V8_EXPORT_PRIVATE HeapConstantType : public NON_EXPORTED_BASE(TypeBase) {
	public:
	Handle<HeapObject> Value() const;
	const HeapObjectRef& Ref() const { return heap_ref_; }

	private:
	friend class Type;
	friend class BitsetType;
	friend Zone;

	static HeapConstantType* New(const HeapObjectRef& heap_ref,
	BitsetType::bitset bitset, Zone* zone) {
	return zone->New<HeapConstantType>(bitset, heap_ref);
	}

	HeapConstantType(BitsetType::bitset bitset, const HeapObjectRef& heap_ref);

	BitsetType::bitset Lub() const { return bitset_; }

	BitsetType::bitset bitset_;
	HeapObjectRef heap_ref_;
	};

	// -----------------------------------------------------------------------------
	// Superclass for types with variable number of type fields.
	class StructuralType : public TypeBase {
	public:
	int LengthForTesting() const { return Length(); }

	protected:
	friend class Type;

	int Length() const { return length_; }

	Type Get(int i) const {
	DCHECK(0 <= i && i < this->Length());
	return elements_[i];
	}

	void Set(int i, Type type) {
	DCHECK(0 <= i && i < this->Length());
	elements_[i] = type;
	}

	void Shrink(int length) {
	DCHECK(2 <= length && length <= this->Length());
	length_ = length;
	}

	StructuralType(Kind kind, int length, Zone* zone)
	: TypeBase(kind), length_(length) {
	elements_ = zone->NewArray<Type>(length);
	}

	private:
	int length_;
	Type* elements_;
	};

	// -----------------------------------------------------------------------------
	// Tuple types.

	class TupleType : public StructuralType {
	public:
	int Arity() const { return this->Length(); }
	Type Element(int i) const { return this->Get(i); }

	void InitElement(int i, Type type) { this->Set(i, type); }

	private:
	friend Type;
	friend Zone;

	TupleType(int length, Zone* zone) : StructuralType(kTuple, length, zone) {}

	static TupleType* New(int length, Zone* zone) {
	return zone->New<TupleType>(length, zone);
	}
	};

	// -----------------------------------------------------------------------------
	// Union types (internal).
	// A union is a structured type with the following invariants:
	// - its length is at least 2
	// - at most one field is a bitset, and it must go into index 0
	// - no field is a union
	// - no field is a subtype of any other field
	class UnionType : public StructuralType {
	private:
	friend Type;
	friend BitsetType;
	friend Zone;

	UnionType(int length, Zone* zone) : StructuralType(kUnion, length, zone) {}

	static UnionType* New(int length, Zone* zone) {
	return zone->New<UnionType>(length, zone);
	}

	bool Wellformed() const;
	};

	} // namespace compiler
	} // namespace internal
	} // namespace v8

	#endif // V8_COMPILER_TYPES_H_