src/types.h - Issue 2309823002: [turbofan] put src/types.[h/cc] into src/compiler/types.[h/cc]

Unified Diff: src/types.h

Issue 2309823002: [turbofan] put src/types.[h/cc] into src/compiler/types.[h/cc] (Closed)

Patch Set: Created 4 years, 3 months ago

Use n/p to move between diff chunks; N/P to move between comments. Draft comments are only viewable by you.

Jump to:

View side-by-side diff with in-line comments

Index: src/types.h

diff --git a/src/types.h b/src/types.h

deleted file mode 100644

index cd8b937e4b1e51c0d70848b2748496af6a9e31ee..0000000000000000000000000000000000000000

--- a/src/types.h

+++ /dev/null

@@ -1,782 +0,0 @@

-// Use of this source code is governed by a BSD-style license that can be

-// found in the LICENSE file.

-#ifndef V8_TYPES_H_

-#define V8_TYPES_H_

-#include "src/conversions.h"

-#include "src/handles.h"

-#include "src/objects.h"

-#include "src/ostreams.h"

-namespace v8 {

-namespace internal {

-// 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).

-//

-// Types consist of two dimensions: semantic (value range) and representation.

-// Both are related through subtyping.

-//

-// SEMANTIC DIMENSION

-//

-// The following equations and inequations hold for the semantic axis:

-//

-// None <= T

-// T <= Any

-//

-// Number = Signed32 \/ Unsigned32 \/ Double

-// Smi <= Signed32

-// Name = String \/ Symbol

-// UniqueName = InternalizedString \/ Symbol

-// InternalizedString < String

-//

-// Receiver = Object \/ Proxy

-// RegExp < Object

-// OtherUndetectable < Object

-// DetectableReceiver = Receiver - OtherUndetectable

-//

-// Constant(x) < T iff instance_type(map(x)) < T

-//

-// REPRESENTATIONAL DIMENSION

-//

-// For the representation axis, the following holds:

-//

-// None <= R

-// R <= Any

-//

-// UntaggedInt = UntaggedInt1 \/ UntaggedInt8 \/

-// UntaggedInt16 \/ UntaggedInt32

-// UntaggedFloat = UntaggedFloat32 \/ UntaggedFloat64

-// UntaggedNumber = UntaggedInt \/ UntaggedFloat

-// Untagged = UntaggedNumber \/ UntaggedPtr

-// Tagged = TaggedInt \/ TaggedPtr

-//

-// Subtyping relates the two dimensions, for example:

-//

-// Number <= Tagged \/ UntaggedNumber

-// Object <= TaggedPtr \/ UntaggedPtr

-//

-// That holds because the semantic type constructors defined by the API create

-// types that allow for all possible representations, and dually, the ones for

-// representation types initially include all semantic ranges. Representations

-// can then e.g. be narrowed for a given semantic type using intersection:

-//

-// SignedSmall /\ TaggedInt (a 'smi')

-// Number /\ TaggedPtr (a heap number)

-//

-// 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.

-// Note that the bitset representation is closed under both Union and Intersect.

-// -----------------------------------------------------------------------------

-// Values for bitset types

-// clang-format off

-#define MASK_BITSET_TYPE_LIST(V) \

- V(Representation, 0xffc00000u) \

- V(Semantic, 0x003ffffeu)

-#define REPRESENTATION(k) ((k) & BitsetType::kRepresentation)

-#define SEMANTIC(k) ((k) & BitsetType::kSemantic)

-#define REPRESENTATION_BITSET_TYPE_LIST(V) \

- V(None, 0) \

- V(UntaggedBit, 1u << 22 | kSemantic) \

- V(UntaggedIntegral8, 1u << 23 | kSemantic) \

- V(UntaggedIntegral16, 1u << 24 | kSemantic) \

- V(UntaggedIntegral32, 1u << 25 | kSemantic) \

- V(UntaggedFloat32, 1u << 26 | kSemantic) \

- V(UntaggedFloat64, 1u << 27 | kSemantic) \

- V(UntaggedSimd128, 1u << 28 | kSemantic) \

- V(UntaggedPointer, 1u << 29 | kSemantic) \

- V(TaggedSigned, 1u << 30 | kSemantic) \

- V(TaggedPointer, 1u << 31 | kSemantic) \

- \

- V(UntaggedIntegral, kUntaggedBit | kUntaggedIntegral8 | \

- kUntaggedIntegral16 | kUntaggedIntegral32) \

- V(UntaggedFloat, kUntaggedFloat32 | kUntaggedFloat64) \

- V(UntaggedNumber, kUntaggedIntegral | kUntaggedFloat) \

- V(Untagged, kUntaggedNumber | kUntaggedPointer) \

- V(Tagged, kTaggedSigned | kTaggedPointer)

-#define INTERNAL_BITSET_TYPE_LIST(V) \

- V(OtherUnsigned31, 1u << 1 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(OtherUnsigned32, 1u << 2 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(OtherSigned32, 1u << 3 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(OtherNumber, 1u << 4 | REPRESENTATION(kTagged | kUntaggedNumber))

-#define SEMANTIC_BITSET_TYPE_LIST(V) \

- V(Negative31, 1u << 5 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(Null, 1u << 6 | REPRESENTATION(kTaggedPointer)) \

- V(Undefined, 1u << 7 | REPRESENTATION(kTaggedPointer)) \

- V(Boolean, 1u << 8 | REPRESENTATION(kTaggedPointer)) \

- V(Unsigned30, 1u << 9 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(MinusZero, 1u << 10 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(NaN, 1u << 11 | REPRESENTATION(kTagged | kUntaggedNumber)) \

- V(Symbol, 1u << 12 | REPRESENTATION(kTaggedPointer)) \

- V(InternalizedString, 1u << 13 | REPRESENTATION(kTaggedPointer)) \

- V(OtherString, 1u << 14 | REPRESENTATION(kTaggedPointer)) \

- V(Simd, 1u << 15 | REPRESENTATION(kTaggedPointer)) \

- V(OtherObject, 1u << 17 | REPRESENTATION(kTaggedPointer)) \

- V(OtherUndetectable, 1u << 16 | REPRESENTATION(kTaggedPointer)) \

- V(Proxy, 1u << 18 | REPRESENTATION(kTaggedPointer)) \

- V(Function, 1u << 19 | REPRESENTATION(kTaggedPointer)) \

- V(Hole, 1u << 20 | REPRESENTATION(kTaggedPointer)) \

- V(OtherInternal, 1u << 21 | REPRESENTATION(kTagged | kUntagged)) \

- \

- 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(PlainNumber, kIntegral32 | kOtherNumber) \

- V(OrderedNumber, kPlainNumber | kMinusZero) \

- V(MinusZeroOrNaN, kMinusZero | kNaN) \

- V(Number, kOrderedNumber | kNaN) \

- V(String, kInternalizedString | kOtherString) \

- V(UniqueName, kSymbol | kInternalizedString) \

- V(Name, kSymbol | kString) \

- V(BooleanOrNumber, kBoolean | kNumber) \

- V(BooleanOrNullOrNumber, kBooleanOrNumber | kNull) \

- V(BooleanOrNullOrUndefined, kBoolean | kNull | kUndefined) \

- V(NullOrNumber, kNull | kNumber) \

- V(NullOrUndefined, kNull | kUndefined) \

- V(Undetectable, kNullOrUndefined | kOtherUndetectable) \

- V(NumberOrOddball, kNumber | kNullOrUndefined | kBoolean | kHole) \

- V(NumberOrSimdOrString, kNumber | kSimd | kString) \

- V(NumberOrString, kNumber | kString) \

- V(NumberOrUndefined, kNumber | kUndefined) \

- V(PlainPrimitive, kNumberOrString | kBoolean | kNullOrUndefined) \

- V(Primitive, kSymbol | kSimd | kPlainPrimitive) \

- V(DetectableReceiver, kFunction | kOtherObject | kProxy) \

- V(Object, kFunction | kOtherObject | kOtherUndetectable) \

- V(Receiver, kObject | kProxy) \

- V(StringOrReceiver, kString | kReceiver) \

- V(Unique, kBoolean | kUniqueName | kNull | kUndefined | \

- kReceiver) \

- V(Internal, kHole | kOtherInternal) \

- V(NonInternal, kPrimitive | kReceiver) \

- V(NonNumber, 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 PROPER_BITSET_TYPE_LIST(V) \

- REPRESENTATION_BITSET_TYPE_LIST(V) \

- SEMANTIC_BITSET_TYPE_LIST(V)

-#define BITSET_TYPE_LIST(V) \

- MASK_BITSET_TYPE_LIST(V) \

- REPRESENTATION_BITSET_TYPE_LIST(V) \

- INTERNAL_BITSET_TYPE_LIST(V) \

- SEMANTIC_BITSET_TYPE_LIST(V)

-class Type;

-// -----------------------------------------------------------------------------

-// Bitset types (internal).

-class BitsetType {

- public:

- typedef uint32_t bitset; // 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();

- bitset Bitset() {

- return static_cast<bitset>(reinterpret_cast<uintptr_t>(this) ^ 1u);

- }

- static bool IsInhabited(bitset bits) {

- return SEMANTIC(bits) != kNone && REPRESENTATION(bits) != kNone;

- }

- static bool SemanticIsInhabited(bitset bits) {

- return SEMANTIC(bits) != kNone;

- }

- static bool Is(bitset bits1, bitset bits2) {

- return (bits1 | bits2) == bits2;

- }

- static double Min(bitset);

- static double Max(bitset);

- static bitset Glb(Type* type); // greatest lower bound that's a bitset

- static bitset Glb(double min, double max);

- static bitset Lub(Type* type); // least upper bound that's a bitset

- static bitset Lub(i::Map* map);

- static bitset Lub(i::Object* value);

- 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);

- static bool IsBitset(Type* type) {

- return reinterpret_cast<uintptr_t>(type) & 1;

- }

- static Type* NewForTesting(bitset bits) { return New(bits); }

- private:

- friend class Type;

- static Type* New(bitset bits) {

- return reinterpret_cast<Type*>(static_cast<uintptr_t>(bits | 1u));

- }

- struct Boundary {

- bitset internal;

- bitset external;

- double min;

- };

- static const Boundary BoundariesArray[];

- static inline const Boundary* Boundaries();

- static inline size_t BoundariesSize();

-};

-// -----------------------------------------------------------------------------

-// Superclass for non-bitset types (internal).

-class TypeBase {

- protected:

- friend class Type;

- enum Kind {

- kConstant,

- kTuple,

- kUnion,

- kRange

- };

- Kind kind() const { return kind_; }

- explicit TypeBase(Kind kind) : kind_(kind) {}

- static bool IsKind(Type* type, Kind kind) {

- if (BitsetType::IsBitset(type)) return false;

- TypeBase* base = reinterpret_cast<TypeBase*>(type);

- return base->kind() == kind;

- }

- // The hacky conversion to/from Type*.

- static Type* AsType(TypeBase* type) { return reinterpret_cast<Type*>(type); }

- static TypeBase* FromType(Type* type) {

- return reinterpret_cast<TypeBase*>(type);

- }

- private:

- Kind kind_;

-};

-// -----------------------------------------------------------------------------

-// Constant types.

-class ConstantType : public TypeBase {

- public:

- i::Handle<i::Object> Value() { return object_; }

- private:

- friend class Type;

- friend class BitsetType;

- static Type* New(i::Handle<i::Object> value, Zone* zone) {

- BitsetType::bitset bitset = BitsetType::Lub(*value);

- return AsType(new (zone->New(sizeof(ConstantType)))

- ConstantType(bitset, value));

- }

- static ConstantType* cast(Type* type) {

- DCHECK(IsKind(type, kConstant));

- return static_cast<ConstantType*>(FromType(type));

- }

- ConstantType(BitsetType::bitset bitset, i::Handle<i::Object> object)

- : TypeBase(kConstant), bitset_(bitset), object_(object) {}

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

- BitsetType::bitset bitset_;

- Handle<i::Object> object_;

-};

-// TODO(neis): Also cache value if numerical.

-// TODO(neis): Allow restricting the representation.

-// -----------------------------------------------------------------------------

-// Range types.

-class RangeType : public TypeBase {

- public:

- struct Limits {

- double min;

- double max;

- Limits(double min, double max) : min(min), max(max) {}

- explicit Limits(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() { return limits_.min; }

- double Max() { return limits_.max; }

- private:

- friend class Type;

- friend class BitsetType;

- friend class UnionType;

- static Type* New(double min, double max, BitsetType::bitset representation,

- Zone* zone) {

- return New(Limits(min, max), representation, zone);

- }

- static bool IsInteger(double x) {

- return nearbyint(x) == x && !i::IsMinusZero(x); // Allows for infinities.

- }

- static Type* New(Limits lim, BitsetType::bitset representation, Zone* zone) {

- DCHECK(IsInteger(lim.min) && IsInteger(lim.max));

- DCHECK(lim.min <= lim.max);

- DCHECK(REPRESENTATION(representation) == representation);

- BitsetType::bitset bits =

- SEMANTIC(BitsetType::Lub(lim.min, lim.max)) | representation;

- return AsType(new (zone->New(sizeof(RangeType))) RangeType(bits, lim));

- }

- static RangeType* cast(Type* type) {

- DCHECK(IsKind(type, kRange));

- return static_cast<RangeType*>(FromType(type));

- }

- RangeType(BitsetType::bitset bitset, Limits limits)

- : TypeBase(kRange), bitset_(bitset), limits_(limits) {}

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

- BitsetType::bitset bitset_;

- Limits limits_;

-};

-// -----------------------------------------------------------------------------

-// Superclass for types with variable number of type fields.

-class StructuralType : public TypeBase {

- public:

- int LengthForTesting() { return Length(); }

- protected:

- friend class Type;

- int Length() { return length_; }

- Type* Get(int i) {

- 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, i::Zone* zone)

- : TypeBase(kind), length_(length) {

- elements_ = reinterpret_cast<Type**>(zone->New(sizeof(Type*) * length));

- }

- private:

- int length_;

- Type** elements_;

-};

-// -----------------------------------------------------------------------------

-// Tuple types.

-class TupleType : public StructuralType {

- public:

- int Arity() { return this->Length(); }

- Type* Element(int i) { return this->Get(i); }

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

- private:

- friend class Type;

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

- static Type* New(int length, Zone* zone) {

- return AsType(new (zone->New(sizeof(TupleType))) TupleType(length, zone));

- }

- static TupleType* cast(Type* type) {

- DCHECK(IsKind(type, kTuple));

- return static_cast<TupleType*>(FromType(type));

- }

-};

-// -----------------------------------------------------------------------------

-// 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;

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

- static Type* New(int length, Zone* zone) {

- return AsType(new (zone->New(sizeof(UnionType))) UnionType(length, zone));

- }

- static UnionType* cast(Type* type) {

- DCHECK(IsKind(type, kUnion));

- return static_cast<UnionType*>(FromType(type));

- }

- bool Wellformed();

-};

-class Type {

- public:

- typedef BitsetType::bitset bitset; // Internal

-// Constructors.

-#define DEFINE_TYPE_CONSTRUCTOR(type, value) \

- static Type* type() { return BitsetType::New(BitsetType::k##type); }

- PROPER_BITSET_TYPE_LIST(DEFINE_TYPE_CONSTRUCTOR)

-#undef DEFINE_TYPE_CONSTRUCTOR

- static Type* SignedSmall() {

- return BitsetType::New(BitsetType::SignedSmall());

- }

- static Type* UnsignedSmall() {

- return BitsetType::New(BitsetType::UnsignedSmall());

- }

- static Type* Constant(i::Handle<i::Object> value, Zone* zone) {

- return ConstantType::New(value, zone);

- }

- static Type* Range(double min, double max, Zone* zone) {

- return RangeType::New(min, max, REPRESENTATION(BitsetType::kTagged |

- BitsetType::kUntaggedNumber),

- zone);

- }

- static Type* Tuple(Type* first, Type* second, Type* third, Zone* zone) {

- Type* tuple = TupleType::New(3, zone);

- tuple->AsTuple()->InitElement(0, first);

- tuple->AsTuple()->InitElement(1, second);

- tuple->AsTuple()->InitElement(2, third);

- return tuple;

- }

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

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

- static Type* Of(double value, Zone* zone) {

- return BitsetType::New(BitsetType::ExpandInternals(BitsetType::Lub(value)));

- }

- static Type* Of(i::Object* value, Zone* zone) {

- return BitsetType::New(BitsetType::ExpandInternals(BitsetType::Lub(value)));

- }

- static Type* Of(i::Handle<i::Object> value, Zone* zone) {

- return Of(*value, zone);

- }

- static Type* For(i::Map* map) {

- return BitsetType::New(BitsetType::ExpandInternals(BitsetType::Lub(map)));

- }

- static Type* For(i::Handle<i::Map> map) { return For(*map); }

- // Extraction of components.

- static Type* Representation(Type* t, Zone* zone);

- static Type* Semantic(Type* t, Zone* zone);

- // Predicates.

- bool IsInhabited() { return BitsetType::IsInhabited(this->BitsetLub()); }

- bool Is(Type* that) { return this == that || this->SlowIs(that); }

- bool Maybe(Type* that);

- bool Equals(Type* that) { return this->Is(that) && that->Is(this); }

- // Equivalent to Constant(val)->Is(this), but avoiding allocation.

- bool Contains(i::Object* val);

- bool Contains(i::Handle<i::Object> val) { return this->Contains(*val); }

- // Inspection.

- bool IsRange() { return IsKind(TypeBase::kRange); }

- bool IsConstant() { return IsKind(TypeBase::kConstant); }

- bool IsTuple() { return IsKind(TypeBase::kTuple); }

- ConstantType* AsConstant() { return ConstantType::cast(this); }

- RangeType* AsRange() { return RangeType::cast(this); }

- TupleType* AsTuple() { return TupleType::cast(this); }

- // Minimum and maximum of a numeric type.

- // These functions do not distinguish between -0 and +0. If the type equals

- // kNaN, they return NaN; otherwise kNaN is ignored. Only call these

- // functions on subtypes of Number.

- double Min();

- double Max();

- // Extracts a range from the type: if the type is a range or a union

- // containing a range, that range is returned; otherwise, NULL is returned.

- Type* GetRange();

- static bool IsInteger(i::Object* x);

- static bool IsInteger(double x) {

- return nearbyint(x) == x && !i::IsMinusZero(x); // Allows for infinities.

- }

- int NumConstants();

- template <class T>

- class Iterator {

- public:

- bool Done() const { return index_ < 0; }

- i::Handle<T> Current();

- void Advance();

- private:

- friend class Type;

- Iterator() : index_(-1) {}

- explicit Iterator(Type* type) : type_(type), index_(-1) { Advance(); }

- inline bool matches(Type* type);

- inline Type* get_type();

- Type* type_;

- int index_;

- };

- Iterator<i::Object> Constants() {

- if (this->IsBitset()) return Iterator<i::Object>();

- return Iterator<i::Object>(this);

- }

- // Printing.

- enum PrintDimension { BOTH_DIMS, SEMANTIC_DIM, REPRESENTATION_DIM };

- void PrintTo(std::ostream& os, PrintDimension dim = BOTH_DIMS); // NOLINT

-#ifdef DEBUG

- void Print();

-#endif

- // Helpers for testing.

- bool IsBitsetForTesting() { return IsBitset(); }

- bool IsUnionForTesting() { return IsUnion(); }

- bitset AsBitsetForTesting() { return AsBitset(); }

- UnionType* AsUnionForTesting() { return AsUnion(); }

- private:

- // Friends.

- template <class>

- friend class Iterator;

- friend BitsetType;

- friend UnionType;

- // Internal inspection.

- bool IsKind(TypeBase::Kind kind) { return TypeBase::IsKind(this, kind); }

- bool IsNone() { return this == None(); }

- bool IsAny() { return this == Any(); }

- bool IsBitset() { return BitsetType::IsBitset(this); }

- bool IsUnion() { return IsKind(TypeBase::kUnion); }

- bitset AsBitset() {

- DCHECK(this->IsBitset());

- return reinterpret_cast<BitsetType*>(this)->Bitset();

- }

- UnionType* AsUnion() { return UnionType::cast(this); }

- bitset Representation();

- // Auxiliary functions.

- bool SemanticMaybe(Type* that);

- bitset BitsetGlb() { return BitsetType::Glb(this); }

- bitset BitsetLub() { return BitsetType::Lub(this); }

- bool SlowIs(Type* that);

- bool SemanticIs(Type* that);

- static bool Overlap(RangeType* lhs, RangeType* rhs);

- static bool Contains(RangeType* lhs, RangeType* rhs);

- static bool Contains(RangeType* range, ConstantType* constant);

- static bool Contains(RangeType* range, i::Object* val);

- 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);

- 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(Type* unioned, int size, Zone* zone);

- static Type* NormalizeRangeAndBitset(Type* range, bitset* bits, Zone* zone);

-};

-// -----------------------------------------------------------------------------

-// Type bounds. A simple struct to represent a pair of lower/upper types.

-struct Bounds {

- Type* lower;

- Type* upper;

- Bounds()

- : // Make sure accessing uninitialized bounds crashes big-time.

- lower(nullptr),

- upper(nullptr) {}

- explicit Bounds(Type* t) : lower(t), upper(t) {}

- Bounds(Type* l, Type* u) : lower(l), upper(u) { DCHECK(lower->Is(upper)); }

- // Unrestricted bounds.

- static Bounds Unbounded() { return Bounds(Type::None(), Type::Any()); }

- // Meet: both b1 and b2 are known to hold.

- static Bounds Both(Bounds b1, Bounds b2, Zone* zone) {

- Type* lower = Type::Union(b1.lower, b2.lower, zone);

- Type* upper = Type::Intersect(b1.upper, b2.upper, zone);

- // Lower bounds are considered approximate, correct as necessary.

- if (!lower->Is(upper)) lower = upper;

- return Bounds(lower, upper);

- }

- // Join: either b1 or b2 is known to hold.

- static Bounds Either(Bounds b1, Bounds b2, Zone* zone) {

- Type* lower = Type::Intersect(b1.lower, b2.lower, zone);

- Type* upper = Type::Union(b1.upper, b2.upper, zone);

- return Bounds(lower, upper);

- }

- static Bounds NarrowLower(Bounds b, Type* t, Zone* zone) {

- Type* lower = Type::Union(b.lower, t, zone);

- // Lower bounds are considered approximate, correct as necessary.

- if (!lower->Is(b.upper)) lower = b.upper;

- return Bounds(lower, b.upper);

- }

- static Bounds NarrowUpper(Bounds b, Type* t, Zone* zone) {

- Type* lower = b.lower;

- Type* upper = Type::Intersect(b.upper, t, zone);

- // Lower bounds are considered approximate, correct as necessary.

- if (!lower->Is(upper)) lower = upper;

- return Bounds(lower, upper);

- }

- bool Narrows(Bounds that) {

- return that.lower->Is(this->lower) && this->upper->Is(that.upper);

- }

-};

-} // namespace internal

-} // namespace v8

-#endif // V8_TYPES_H_

« no previous file with comments | « src/compiler/types.cc ('k') | src/types.cc » ('j') | test/cctest/test-field-type-tracking.cc » ('J')