src/v8/src/objects/slots.h - cobalt - Git at Google

 // Copyright 2018 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_OBJECTS_SLOTS_H_
 #define V8_OBJECTS_SLOTS_H_

 #include "src/base/memory.h"
 #include "src/common/globals.h"

 namespace v8 {
 namespace internal {

 class Object;

 template <typename Subclass, typename Data,
           size_t SlotDataAlignment = sizeof(Data)>
 class SlotBase {
  public:
   using TData = Data;

   static constexpr size_t kSlotDataSize = sizeof(Data);
   static constexpr size_t kSlotDataAlignment = SlotDataAlignment;

   Subclass& operator++() {  // Prefix increment.
     ptr_ += kSlotDataSize;
     return *static_cast<Subclass*>(this);
   }
   Subclass operator++(int) {  // Postfix increment.
     Subclass result = *static_cast<Subclass*>(this);
     ptr_ += kSlotDataSize;
     return result;
   }
   Subclass& operator--() {  // Prefix decrement.
     ptr_ -= kSlotDataSize;
     return *static_cast<Subclass*>(this);
   }
   Subclass operator--(int) {  // Postfix decrement.
     Subclass result = *static_cast<Subclass*>(this);
     ptr_ -= kSlotDataSize;
     return result;
   }

   bool operator<(const SlotBase& other) const { return ptr_ < other.ptr_; }
   bool operator<=(const SlotBase& other) const { return ptr_ <= other.ptr_; }
   bool operator>(const SlotBase& other) const { return ptr_ > other.ptr_; }
   bool operator>=(const SlotBase& other) const { return ptr_ >= other.ptr_; }
   bool operator==(const SlotBase& other) const { return ptr_ == other.ptr_; }
   bool operator!=(const SlotBase& other) const { return ptr_ != other.ptr_; }
   size_t operator-(const SlotBase& other) const {
     DCHECK_GE(ptr_, other.ptr_);
     return static_cast<size_t>((ptr_ - other.ptr_) / kSlotDataSize);
   }
   Subclass operator-(int i) const { return Subclass(ptr_ - i * kSlotDataSize); }
   Subclass operator+(int i) const { return Subclass(ptr_ + i * kSlotDataSize); }
   friend Subclass operator+(int i, const Subclass& slot) {
     return Subclass(slot.ptr_ + i * kSlotDataSize);
   }
   Subclass& operator+=(int i) {
     ptr_ += i * kSlotDataSize;
     return *static_cast<Subclass*>(this);
   }
   Subclass operator-(int i) { return Subclass(ptr_ - i * kSlotDataSize); }
   Subclass& operator-=(int i) {
     ptr_ -= i * kSlotDataSize;
     return *static_cast<Subclass*>(this);
   }

   void* ToVoidPtr() const { return reinterpret_cast<void*>(address()); }

   Address address() const { return ptr_; }
   // For symmetry with Handle.
   TData* location() const { return reinterpret_cast<TData*>(ptr_); }

  protected:
   explicit SlotBase(Address ptr) : ptr_(ptr) {
     DCHECK(IsAligned(ptr, kSlotDataAlignment));
   }

  private:
   // This field usually describes an on-heap address (a slot within an object),
   // so its type should not be a pointer to another C++ wrapper class.
   // Type safety is provided by well-defined conversion operations.
   Address ptr_;
 };

 // An FullObjectSlot instance describes a kSystemPointerSize-sized field
 // ("slot") holding a tagged pointer (smi or strong heap object).
 // Its address() is the address of the slot.
 // The slot's contents can be read and written using operator* and store().
 class FullObjectSlot : public SlotBase<FullObjectSlot, Address> {
  public:
   using TObject = Object;
   using THeapObjectSlot = FullHeapObjectSlot;

   // Tagged value stored in this slot is guaranteed to never be a weak pointer.
   static constexpr bool kCanBeWeak = false;

   FullObjectSlot() : SlotBase(kNullAddress) {}
   explicit FullObjectSlot(Address ptr) : SlotBase(ptr) {}
   explicit FullObjectSlot(const Address* ptr)
       : SlotBase(reinterpret_cast<Address>(ptr)) {}
   inline explicit FullObjectSlot(Object* object);
   template <typename T>
   explicit FullObjectSlot(SlotBase<T, TData, kSlotDataAlignment> slot)
       : SlotBase(slot.address()) {}

   // Compares memory representation of a value stored in the slot with given
   // raw value.
   inline bool contains_value(Address raw_value) const;

   inline const Object operator*() const;
   inline void store(Object value) const;

   inline Object Acquire_Load() const;
   inline Object Relaxed_Load() const;
   inline void Relaxed_Store(Object value) const;
   inline void Release_Store(Object value) const;
   inline Object Release_CompareAndSwap(Object old, Object target) const;
 };

 // A FullMaybeObjectSlot instance describes a kSystemPointerSize-sized field
 // ("slot") holding a possibly-weak tagged pointer (think: MaybeObject).
 // Its address() is the address of the slot.
 // The slot's contents can be read and written using operator* and store().
 class FullMaybeObjectSlot
     : public SlotBase<FullMaybeObjectSlot, Address, kSystemPointerSize> {
  public:
   using TObject = MaybeObject;
   using THeapObjectSlot = FullHeapObjectSlot;

   // Tagged value stored in this slot can be a weak pointer.
   static constexpr bool kCanBeWeak = true;

   FullMaybeObjectSlot() : SlotBase(kNullAddress) {}
   explicit FullMaybeObjectSlot(Address ptr) : SlotBase(ptr) {}
   explicit FullMaybeObjectSlot(Object* ptr)
       : SlotBase(reinterpret_cast<Address>(ptr)) {}
   explicit FullMaybeObjectSlot(MaybeObject* ptr)
       : SlotBase(reinterpret_cast<Address>(ptr)) {}
   template <typename T>
   explicit FullMaybeObjectSlot(SlotBase<T, TData, kSlotDataAlignment> slot)
       : SlotBase(slot.address()) {}

   inline const MaybeObject operator*() const;
   inline void store(MaybeObject value) const;

   inline MaybeObject Relaxed_Load() const;
   inline void Relaxed_Store(MaybeObject value) const;
   inline void Release_CompareAndSwap(MaybeObject old, MaybeObject target) const;
 };

 // A FullHeapObjectSlot instance describes a kSystemPointerSize-sized field
 // ("slot") holding a weak or strong pointer to a heap object (think:
 // HeapObjectReference).
 // Its address() is the address of the slot.
 // The slot's contents can be read and written using operator* and store().
 // In case it is known that that slot contains a strong heap object pointer,
 // ToHeapObject() can be used to retrieve that heap object.
 class FullHeapObjectSlot : public SlotBase<FullHeapObjectSlot, Address> {
  public:
   FullHeapObjectSlot() : SlotBase(kNullAddress) {}
   explicit FullHeapObjectSlot(Address ptr) : SlotBase(ptr) {}
   explicit FullHeapObjectSlot(Object* ptr)
       : SlotBase(reinterpret_cast<Address>(ptr)) {}
   template <typename T>
   explicit FullHeapObjectSlot(SlotBase<T, TData, kSlotDataAlignment> slot)
       : SlotBase(slot.address()) {}

   inline const HeapObjectReference operator*() const;
   inline void store(HeapObjectReference value) const;

   inline HeapObject ToHeapObject() const;

   inline void StoreHeapObject(HeapObject value) const;
 };

 // TODO(ishell, v8:8875): When pointer compression is enabled the [u]intptr_t
 // and double fields are only kTaggedSize aligned so in order to avoid undefined
 // behavior in C++ code we use this iterator adaptor when using STL algorithms
 // with unaligned pointers.
 // It will be removed once all v8:8875 is fixed and all the full pointer and
 // double values in compressed V8 heap are properly aligned.
 template <typename T>
 class UnalignedSlot : public SlotBase<UnalignedSlot<T>, T, 1> {
  public:
   // This class is a stand-in for "T&" that uses custom read/write operations
   // for the actual memory accesses.
   class Reference {
    public:
     explicit Reference(Address address) : address_(address) {}
     Reference(const Reference&) V8_NOEXCEPT = default;

     Reference& operator=(const Reference& other) V8_NOEXCEPT {
       base::WriteUnalignedValue<T>(address_, other.value());
       return *this;
     }
     Reference& operator=(T value) {
       base::WriteUnalignedValue<T>(address_, value);
       return *this;
     }

     // Values of type UnalignedSlot::reference must be implicitly convertible
     // to UnalignedSlot::value_type.
     operator T() const { return value(); }

     void swap(Reference& other) {
       T tmp = value();
       base::WriteUnalignedValue<T>(address_, other.value());
       base::WriteUnalignedValue<T>(other.address_, tmp);
     }

     bool operator<(const Reference& other) const {
       return value() < other.value();
     }

     bool operator==(const Reference& other) const {
       return value() == other.value();
     }

    private:
     T value() const { return base::ReadUnalignedValue<T>(address_); }

     Address address_;
   };

   // The rest of this class follows C++'s "RandomAccessIterator" requirements.
   // Most of the heavy lifting is inherited from SlotBase.
   using difference_type = int;
   using value_type = T;
   using reference = Reference;
   using pointer = T*;
   using iterator_category = std::random_access_iterator_tag;

   UnalignedSlot() : SlotBase<UnalignedSlot<T>, T, 1>(kNullAddress) {}
   explicit UnalignedSlot(Address address)
       : SlotBase<UnalignedSlot<T>, T, 1>(address) {}
   explicit UnalignedSlot(T* address)
       : SlotBase<UnalignedSlot<T>, T, 1>(reinterpret_cast<Address>(address)) {}

   Reference operator*() const {
     return Reference(SlotBase<UnalignedSlot<T>, T, 1>::address());
   }
   Reference operator[](difference_type i) const {
     return Reference(SlotBase<UnalignedSlot<T>, T, 1>::address() +
                      i * sizeof(T));
   }

   friend void swap(Reference lhs, Reference rhs) { lhs.swap(rhs); }

   friend difference_type operator-(UnalignedSlot a, UnalignedSlot b) {
     return static_cast<int>(a.address() - b.address()) / sizeof(T);
   }
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_OBJECTS_SLOTS_H_
	// Copyright 2018 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_OBJECTS_SLOTS_H_
	#define V8_OBJECTS_SLOTS_H_

	#include "src/base/memory.h"
	#include "src/common/globals.h"

	namespace v8 {
	namespace internal {

	class Object;

	template <typename Subclass, typename Data,
	size_t SlotDataAlignment = sizeof(Data)>
	class SlotBase {
	public:
	using TData = Data;

	static constexpr size_t kSlotDataSize = sizeof(Data);
	static constexpr size_t kSlotDataAlignment = SlotDataAlignment;

	Subclass& operator++() { // Prefix increment.
	ptr_ += kSlotDataSize;
	return static_cast<Subclass>(this);
	}
	Subclass operator++(int) { // Postfix increment.
	Subclass result = static_cast<Subclass>(this);
	ptr_ += kSlotDataSize;
	return result;
	}
	Subclass& operator--() { // Prefix decrement.
	ptr_ -= kSlotDataSize;
	return static_cast<Subclass>(this);
	}
	Subclass operator--(int) { // Postfix decrement.
	Subclass result = static_cast<Subclass>(this);
	ptr_ -= kSlotDataSize;
	return result;
	}

	bool operator<(const SlotBase& other) const { return ptr_ < other.ptr_; }
	bool operator<=(const SlotBase& other) const { return ptr_ <= other.ptr_; }
	bool operator>(const SlotBase& other) const { return ptr_ > other.ptr_; }
	bool operator>=(const SlotBase& other) const { return ptr_ >= other.ptr_; }
	bool operator==(const SlotBase& other) const { return ptr_ == other.ptr_; }
	bool operator!=(const SlotBase& other) const { return ptr_ != other.ptr_; }
	size_t operator-(const SlotBase& other) const {
	DCHECK_GE(ptr_, other.ptr_);
	return static_cast<size_t>((ptr_ - other.ptr_) / kSlotDataSize);
	}
	Subclass operator-(int i) const { return Subclass(ptr_ - i * kSlotDataSize); }
	Subclass operator+(int i) const { return Subclass(ptr_ + i * kSlotDataSize); }
	friend Subclass operator+(int i, const Subclass& slot) {
	return Subclass(slot.ptr_ + i * kSlotDataSize);
	}
	Subclass& operator+=(int i) {
	ptr_ += i * kSlotDataSize;
	return static_cast<Subclass>(this);
	}
	Subclass operator-(int i) { return Subclass(ptr_ - i * kSlotDataSize); }
	Subclass& operator-=(int i) {
	ptr_ -= i * kSlotDataSize;
	return static_cast<Subclass>(this);
	}

	void* ToVoidPtr() const { return reinterpret_cast<void*>(address()); }

	Address address() const { return ptr_; }
	// For symmetry with Handle.
	TData* location() const { return reinterpret_cast<TData*>(ptr_); }

	protected:
	explicit SlotBase(Address ptr) : ptr_(ptr) {
	DCHECK(IsAligned(ptr, kSlotDataAlignment));
	}

	private:
	// This field usually describes an on-heap address (a slot within an object),
	// so its type should not be a pointer to another C++ wrapper class.
	// Type safety is provided by well-defined conversion operations.
	Address ptr_;
	};

	// An FullObjectSlot instance describes a kSystemPointerSize-sized field
	// ("slot") holding a tagged pointer (smi or strong heap object).
	// Its address() is the address of the slot.
	// The slot's contents can be read and written using operator* and store().
	class FullObjectSlot : public SlotBase<FullObjectSlot, Address> {
	public:
	using TObject = Object;
	using THeapObjectSlot = FullHeapObjectSlot;

	// Tagged value stored in this slot is guaranteed to never be a weak pointer.
	static constexpr bool kCanBeWeak = false;

	FullObjectSlot() : SlotBase(kNullAddress) {}
	explicit FullObjectSlot(Address ptr) : SlotBase(ptr) {}
	explicit FullObjectSlot(const Address* ptr)
	: SlotBase(reinterpret_cast<Address>(ptr)) {}
	inline explicit FullObjectSlot(Object* object);
	template <typename T>
	explicit FullObjectSlot(SlotBase<T, TData, kSlotDataAlignment> slot)
	: SlotBase(slot.address()) {}

	// Compares memory representation of a value stored in the slot with given
	// raw value.
	inline bool contains_value(Address raw_value) const;

	inline const Object operator*() const;
	inline void store(Object value) const;

	inline Object Acquire_Load() const;
	inline Object Relaxed_Load() const;
	inline void Relaxed_Store(Object value) const;
	inline void Release_Store(Object value) const;
	inline Object Release_CompareAndSwap(Object old, Object target) const;
	};

	// A FullMaybeObjectSlot instance describes a kSystemPointerSize-sized field
	// ("slot") holding a possibly-weak tagged pointer (think: MaybeObject).
	// Its address() is the address of the slot.
	// The slot's contents can be read and written using operator* and store().
	class FullMaybeObjectSlot
	: public SlotBase<FullMaybeObjectSlot, Address, kSystemPointerSize> {
	public:
	using TObject = MaybeObject;
	using THeapObjectSlot = FullHeapObjectSlot;

	// Tagged value stored in this slot can be a weak pointer.
	static constexpr bool kCanBeWeak = true;

	FullMaybeObjectSlot() : SlotBase(kNullAddress) {}
	explicit FullMaybeObjectSlot(Address ptr) : SlotBase(ptr) {}
	explicit FullMaybeObjectSlot(Object* ptr)
	: SlotBase(reinterpret_cast<Address>(ptr)) {}
	explicit FullMaybeObjectSlot(MaybeObject* ptr)
	: SlotBase(reinterpret_cast<Address>(ptr)) {}
	template <typename T>
	explicit FullMaybeObjectSlot(SlotBase<T, TData, kSlotDataAlignment> slot)
	: SlotBase(slot.address()) {}

	inline const MaybeObject operator*() const;
	inline void store(MaybeObject value) const;

	inline MaybeObject Relaxed_Load() const;
	inline void Relaxed_Store(MaybeObject value) const;
	inline void Release_CompareAndSwap(MaybeObject old, MaybeObject target) const;
	};

	// A FullHeapObjectSlot instance describes a kSystemPointerSize-sized field
	// ("slot") holding a weak or strong pointer to a heap object (think:
	// HeapObjectReference).
	// Its address() is the address of the slot.
	// The slot's contents can be read and written using operator* and store().
	// In case it is known that that slot contains a strong heap object pointer,
	// ToHeapObject() can be used to retrieve that heap object.
	class FullHeapObjectSlot : public SlotBase<FullHeapObjectSlot, Address> {
	public:
	FullHeapObjectSlot() : SlotBase(kNullAddress) {}
	explicit FullHeapObjectSlot(Address ptr) : SlotBase(ptr) {}
	explicit FullHeapObjectSlot(Object* ptr)
	: SlotBase(reinterpret_cast<Address>(ptr)) {}
	template <typename T>
	explicit FullHeapObjectSlot(SlotBase<T, TData, kSlotDataAlignment> slot)
	: SlotBase(slot.address()) {}

	inline const HeapObjectReference operator*() const;
	inline void store(HeapObjectReference value) const;

	inline HeapObject ToHeapObject() const;

	inline void StoreHeapObject(HeapObject value) const;
	};

	// TODO(ishell, v8:8875): When pointer compression is enabled the [u]intptr_t
	// and double fields are only kTaggedSize aligned so in order to avoid undefined
	// behavior in C++ code we use this iterator adaptor when using STL algorithms
	// with unaligned pointers.
	// It will be removed once all v8:8875 is fixed and all the full pointer and
	// double values in compressed V8 heap are properly aligned.
	template <typename T>
	class UnalignedSlot : public SlotBase<UnalignedSlot<T>, T, 1> {
	public:
	// This class is a stand-in for "T&" that uses custom read/write operations
	// for the actual memory accesses.
	class Reference {
	public:
	explicit Reference(Address address) : address_(address) {}
	Reference(const Reference&) V8_NOEXCEPT = default;

	Reference& operator=(const Reference& other) V8_NOEXCEPT {
	base::WriteUnalignedValue<T>(address_, other.value());
	return *this;
	}
	Reference& operator=(T value) {
	base::WriteUnalignedValue<T>(address_, value);
	return *this;
	}

	// Values of type UnalignedSlot::reference must be implicitly convertible
	// to UnalignedSlot::value_type.
	operator T() const { return value(); }

	void swap(Reference& other) {
	T tmp = value();
	base::WriteUnalignedValue<T>(address_, other.value());
	base::WriteUnalignedValue<T>(other.address_, tmp);
	}

	bool operator<(const Reference& other) const {
	return value() < other.value();
	}

	bool operator==(const Reference& other) const {
	return value() == other.value();
	}

	private:
	T value() const { return base::ReadUnalignedValue<T>(address_); }

	Address address_;
	};

	// The rest of this class follows C++'s "RandomAccessIterator" requirements.
	// Most of the heavy lifting is inherited from SlotBase.
	using difference_type = int;
	using value_type = T;
	using reference = Reference;
	using pointer = T*;
	using iterator_category = std::random_access_iterator_tag;

	UnalignedSlot() : SlotBase<UnalignedSlot<T>, T, 1>(kNullAddress) {}
	explicit UnalignedSlot(Address address)
	: SlotBase<UnalignedSlot<T>, T, 1>(address) {}
	explicit UnalignedSlot(T* address)
	: SlotBase<UnalignedSlot<T>, T, 1>(reinterpret_cast<Address>(address)) {}

	Reference operator*() const {
	return Reference(SlotBase<UnalignedSlot<T>, T, 1>::address());
	}
	Reference operator[](difference_type i) const {
	return Reference(SlotBase<UnalignedSlot<T>, T, 1>::address() +
	i * sizeof(T));
	}

	friend void swap(Reference lhs, Reference rhs) { lhs.swap(rhs); }

	friend difference_type operator-(UnalignedSlot a, UnalignedSlot b) {
	return static_cast<int>(a.address() - b.address()) / sizeof(T);
	}
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_OBJECTS_SLOTS_H_