src/snapshot/serializer-common.h - fp2-dev/platform/external/v8 - Gitiles

 // Copyright 2016 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_SNAPSHOT_SERIALIZER_COMMON_H_
 #define V8_SNAPSHOT_SERIALIZER_COMMON_H_

 #include "src/address-map.h"
 #include "src/external-reference-table.h"
 #include "src/globals.h"

 namespace v8 {
 namespace internal {

 class Isolate;

 class ExternalReferenceEncoder {
  public:
   explicit ExternalReferenceEncoder(Isolate* isolate);

   uint32_t Encode(Address key) const;

   const char* NameOfAddress(Isolate* isolate, Address address) const;

  private:
   static uint32_t Hash(Address key) {
     return static_cast<uint32_t>(reinterpret_cast<uintptr_t>(key) >>
                                  kPointerSizeLog2);
   }

   base::HashMap* map_;

   DISALLOW_COPY_AND_ASSIGN(ExternalReferenceEncoder);
 };

 class HotObjectsList {
  public:
   HotObjectsList() : index_(0) {
     for (int i = 0; i < kSize; i++) circular_queue_[i] = NULL;
   }

   void Add(HeapObject* object) {
     DCHECK(!AllowHeapAllocation::IsAllowed());
     circular_queue_[index_] = object;
     index_ = (index_ + 1) & kSizeMask;
   }

   HeapObject* Get(int index) {
     DCHECK(!AllowHeapAllocation::IsAllowed());
     DCHECK_NOT_NULL(circular_queue_[index]);
     return circular_queue_[index];
   }

   static const int kNotFound = -1;

   int Find(HeapObject* object) {
     DCHECK(!AllowHeapAllocation::IsAllowed());
     for (int i = 0; i < kSize; i++) {
       if (circular_queue_[i] == object) return i;
     }
     return kNotFound;
   }

   static const int kSize = 8;

  private:
   STATIC_ASSERT(IS_POWER_OF_TWO(kSize));
   static const int kSizeMask = kSize - 1;
   HeapObject* circular_queue_[kSize];
   int index_;

   DISALLOW_COPY_AND_ASSIGN(HotObjectsList);
 };

 // The Serializer/Deserializer class is a common superclass for Serializer and
 // Deserializer which is used to store common constants and methods used by
 // both.
 class SerializerDeserializer : public ObjectVisitor {
  public:
   static void Iterate(Isolate* isolate, ObjectVisitor* visitor);

   // No reservation for large object space necessary.
   static const int kNumberOfPreallocatedSpaces = LAST_PAGED_SPACE + 1;
   static const int kNumberOfSpaces = LAST_SPACE + 1;

  protected:
   static bool CanBeDeferred(HeapObject* o);

   // ---------- byte code range 0x00..0x7f ----------
   // Byte codes in this range represent Where, HowToCode and WhereToPoint.
   // Where the pointed-to object can be found:
   // The static assert below will trigger when the number of preallocated spaces
   // changed. If that happens, update the bytecode ranges in the comments below.
   STATIC_ASSERT(5 == kNumberOfSpaces);
   enum Where {
     // 0x00..0x04  Allocate new object, in specified space.
     kNewObject = 0x00,
     // 0x08..0x0c  Reference to previous object from space.
     kBackref = 0x08,
     // 0x10..0x14  Reference to previous object from space after skip.
     kBackrefWithSkip = 0x10,

     // 0x05       Root array item.
     kRootArray = 0x05,
     // 0x06        Object in the partial snapshot cache.
     kPartialSnapshotCache = 0x06,
     // 0x07        External reference referenced by id.
     kExternalReference = 0x07,

     // 0x0d        Object provided in the attached list.
     kAttachedReference = 0x0d,
     // 0x0e        Builtin code referenced by index.
     kBuiltin = 0x0e,

     // 0x0f        Misc, see below (incl. 0x2f, 0x4f, 0x6f).
     // 0x15..0x1f  Misc, see below (incl. 0x35..0x3f, 0x55..0x5f, 0x75..0x7f).
   };

   static const int kWhereMask = 0x1f;
   static const int kSpaceMask = 7;
   STATIC_ASSERT(kNumberOfSpaces <= kSpaceMask + 1);

   // How to code the pointer to the object.
   enum HowToCode {
     // Straight pointer.
     kPlain = 0,
     // A pointer inlined in code. What this means depends on the architecture.
     kFromCode = 0x20
   };

   static const int kHowToCodeMask = 0x20;

   // Where to point within the object.
   enum WhereToPoint {
     // Points to start of object
     kStartOfObject = 0,
     // Points to instruction in code object or payload of cell.
     kInnerPointer = 0x40
   };

   static const int kWhereToPointMask = 0x40;

   // ---------- Misc ----------
   // Skip.
   static const int kSkip = 0x0f;
   // Do nothing, used for padding.
   static const int kNop = 0x2f;
   // Move to next reserved chunk.
   static const int kNextChunk = 0x4f;
   // Deferring object content.
   static const int kDeferred = 0x6f;
   // Alignment prefixes 0x15..0x17
   static const int kAlignmentPrefix = 0x15;
   // A tag emitted at strategic points in the snapshot to delineate sections.
   // If the deserializer does not find these at the expected moments then it
   // is an indication that the snapshot and the VM do not fit together.
   // Examine the build process for architecture, version or configuration
   // mismatches.
   static const int kSynchronize = 0x18;
   // Repeats of variable length.
   static const int kVariableRepeat = 0x19;
   // Raw data of variable length.
   static const int kVariableRawData = 0x1a;
   // Internal reference encoded as offsets of pc and target from code entry.
   static const int kInternalReference = 0x1b;
   static const int kInternalReferenceEncoded = 0x1c;
   // Used for the source code of the natives, which is in the executable, but
   // is referred to from external strings in the snapshot.
   static const int kNativesStringResource = 0x1d;
   // Used for the source code for compiled stubs, which is in the executable,
   // but is referred to from external strings in the snapshot.
   static const int kExtraNativesStringResource = 0x1e;

   // 8 hot (recently seen or back-referenced) objects with optional skip.
   static const int kNumberOfHotObjects = 8;
   STATIC_ASSERT(kNumberOfHotObjects == HotObjectsList::kSize);
   // 0x38..0x3f
   static const int kHotObject = 0x38;
   // 0x58..0x5f
   static const int kHotObjectWithSkip = 0x58;
   static const int kHotObjectMask = 0x07;

   // 0x1f, 0x35..0x37, 0x55..0x57, 0x75..0x7f unused.

   // ---------- byte code range 0x80..0xff ----------
   // First 32 root array items.
   static const int kNumberOfRootArrayConstants = 0x20;
   // 0x80..0x9f
   static const int kRootArrayConstants = 0x80;
   // 0xa0..0xbf
   static const int kRootArrayConstantsWithSkip = 0xa0;
   static const int kRootArrayConstantsMask = 0x1f;

   // 32 common raw data lengths.
   static const int kNumberOfFixedRawData = 0x20;
   // 0xc0..0xdf
   static const int kFixedRawData = 0xc0;
   static const int kOnePointerRawData = kFixedRawData;
   static const int kFixedRawDataStart = kFixedRawData - 1;

   // 16 repeats lengths.
   static const int kNumberOfFixedRepeat = 0x10;
   // 0xe0..0xef
   static const int kFixedRepeat = 0xe0;
   static const int kFixedRepeatStart = kFixedRepeat - 1;

   // 0xf0..0xff unused.

   // ---------- special values ----------
   static const int kAnyOldSpace = -1;

   // Sentinel after a new object to indicate that double alignment is needed.
   static const int kDoubleAlignmentSentinel = 0;

   // ---------- member variable ----------
   HotObjectsList hot_objects_;
 };

 class SerializedData {
  public:
   class Reservation {
    public:
     explicit Reservation(uint32_t size)
         : reservation_(ChunkSizeBits::encode(size)) {}

     uint32_t chunk_size() const { return ChunkSizeBits::decode(reservation_); }
     bool is_last() const { return IsLastChunkBits::decode(reservation_); }

     void mark_as_last() { reservation_ |= IsLastChunkBits::encode(true); }

    private:
     uint32_t reservation_;
   };

   SerializedData(byte* data, int size)
       : data_(data), size_(size), owns_data_(false) {}
   SerializedData() : data_(NULL), size_(0), owns_data_(false) {}

   ~SerializedData() {
     if (owns_data_) DeleteArray<byte>(data_);
   }

   uint32_t GetMagicNumber() const { return GetHeaderValue(kMagicNumberOffset); }

   class ChunkSizeBits : public BitField<uint32_t, 0, 31> {};
   class IsLastChunkBits : public BitField<bool, 31, 1> {};

   static uint32_t ComputeMagicNumber(ExternalReferenceTable* table) {
     uint32_t external_refs = table->size();
     return 0xC0DE0000 ^ external_refs;
   }

  protected:
   void SetHeaderValue(int offset, uint32_t value) {
     uint32_t* address = reinterpret_cast<uint32_t*>(data_ + offset);
     memcpy(reinterpret_cast<uint32_t*>(address), &value, sizeof(value));
   }

   uint32_t GetHeaderValue(int offset) const {
     uint32_t value;
     memcpy(&value, reinterpret_cast<int*>(data_ + offset), sizeof(value));
     return value;
   }

   void AllocateData(int size);

   static uint32_t ComputeMagicNumber(Isolate* isolate) {
     return ComputeMagicNumber(ExternalReferenceTable::instance(isolate));
   }

   void SetMagicNumber(Isolate* isolate) {
     SetHeaderValue(kMagicNumberOffset, ComputeMagicNumber(isolate));
   }

   static const int kMagicNumberOffset = 0;

   byte* data_;
   int size_;
   bool owns_data_;
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_SNAPSHOT_SERIALIZER_COMMON_H_
	// Copyright 2016 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_SNAPSHOT_SERIALIZER_COMMON_H_
	#define V8_SNAPSHOT_SERIALIZER_COMMON_H_

	#include "src/address-map.h"
	#include "src/external-reference-table.h"
	#include "src/globals.h"

	namespace v8 {
	namespace internal {

	class Isolate;

	class ExternalReferenceEncoder {
	public:
	explicit ExternalReferenceEncoder(Isolate* isolate);

	uint32_t Encode(Address key) const;

	const char* NameOfAddress(Isolate* isolate, Address address) const;

	private:
	static uint32_t Hash(Address key) {
	return static_cast<uint32_t>(reinterpret_cast<uintptr_t>(key) >>
	kPointerSizeLog2);
	}

	base::HashMap* map_;

	DISALLOW_COPY_AND_ASSIGN(ExternalReferenceEncoder);
	};

	class HotObjectsList {
	public:
	HotObjectsList() : index_(0) {
	for (int i = 0; i < kSize; i++) circular_queue_[i] = NULL;
	}

	void Add(HeapObject* object) {
	DCHECK(!AllowHeapAllocation::IsAllowed());
	circular_queue_[index_] = object;
	index_ = (index_ + 1) & kSizeMask;
	}

	HeapObject* Get(int index) {
	DCHECK(!AllowHeapAllocation::IsAllowed());
	DCHECK_NOT_NULL(circular_queue_[index]);
	return circular_queue_[index];
	}

	static const int kNotFound = -1;

	int Find(HeapObject* object) {
	DCHECK(!AllowHeapAllocation::IsAllowed());
	for (int i = 0; i < kSize; i++) {
	if (circular_queue_[i] == object) return i;
	}
	return kNotFound;
	}

	static const int kSize = 8;

	private:
	STATIC_ASSERT(IS_POWER_OF_TWO(kSize));
	static const int kSizeMask = kSize - 1;
	HeapObject* circular_queue_[kSize];
	int index_;

	DISALLOW_COPY_AND_ASSIGN(HotObjectsList);
	};

	// The Serializer/Deserializer class is a common superclass for Serializer and
	// Deserializer which is used to store common constants and methods used by
	// both.
	class SerializerDeserializer : public ObjectVisitor {
	public:
	static void Iterate(Isolate* isolate, ObjectVisitor* visitor);

	// No reservation for large object space necessary.
	static const int kNumberOfPreallocatedSpaces = LAST_PAGED_SPACE + 1;
	static const int kNumberOfSpaces = LAST_SPACE + 1;

	protected:
	static bool CanBeDeferred(HeapObject* o);

	// ---------- byte code range 0x00..0x7f ----------
	// Byte codes in this range represent Where, HowToCode and WhereToPoint.
	// Where the pointed-to object can be found:
	// The static assert below will trigger when the number of preallocated spaces
	// changed. If that happens, update the bytecode ranges in the comments below.
	STATIC_ASSERT(5 == kNumberOfSpaces);
	enum Where {
	// 0x00..0x04 Allocate new object, in specified space.
	kNewObject = 0x00,
	// 0x08..0x0c Reference to previous object from space.
	kBackref = 0x08,
	// 0x10..0x14 Reference to previous object from space after skip.
	kBackrefWithSkip = 0x10,

	// 0x05 Root array item.
	kRootArray = 0x05,
	// 0x06 Object in the partial snapshot cache.
	kPartialSnapshotCache = 0x06,
	// 0x07 External reference referenced by id.
	kExternalReference = 0x07,

	// 0x0d Object provided in the attached list.
	kAttachedReference = 0x0d,
	// 0x0e Builtin code referenced by index.
	kBuiltin = 0x0e,

	// 0x0f Misc, see below (incl. 0x2f, 0x4f, 0x6f).
	// 0x15..0x1f Misc, see below (incl. 0x35..0x3f, 0x55..0x5f, 0x75..0x7f).
	};

	static const int kWhereMask = 0x1f;
	static const int kSpaceMask = 7;
	STATIC_ASSERT(kNumberOfSpaces <= kSpaceMask + 1);

	// How to code the pointer to the object.
	enum HowToCode {
	// Straight pointer.
	kPlain = 0,
	// A pointer inlined in code. What this means depends on the architecture.
	kFromCode = 0x20
	};

	static const int kHowToCodeMask = 0x20;

	// Where to point within the object.
	enum WhereToPoint {
	// Points to start of object
	kStartOfObject = 0,
	// Points to instruction in code object or payload of cell.
	kInnerPointer = 0x40
	};

	static const int kWhereToPointMask = 0x40;

	// ---------- Misc ----------
	// Skip.
	static const int kSkip = 0x0f;
	// Do nothing, used for padding.
	static const int kNop = 0x2f;
	// Move to next reserved chunk.
	static const int kNextChunk = 0x4f;
	// Deferring object content.
	static const int kDeferred = 0x6f;
	// Alignment prefixes 0x15..0x17
	static const int kAlignmentPrefix = 0x15;
	// A tag emitted at strategic points in the snapshot to delineate sections.
	// If the deserializer does not find these at the expected moments then it
	// is an indication that the snapshot and the VM do not fit together.
	// Examine the build process for architecture, version or configuration
	// mismatches.
	static const int kSynchronize = 0x18;
	// Repeats of variable length.
	static const int kVariableRepeat = 0x19;
	// Raw data of variable length.
	static const int kVariableRawData = 0x1a;
	// Internal reference encoded as offsets of pc and target from code entry.
	static const int kInternalReference = 0x1b;
	static const int kInternalReferenceEncoded = 0x1c;
	// Used for the source code of the natives, which is in the executable, but
	// is referred to from external strings in the snapshot.
	static const int kNativesStringResource = 0x1d;
	// Used for the source code for compiled stubs, which is in the executable,
	// but is referred to from external strings in the snapshot.
	static const int kExtraNativesStringResource = 0x1e;

	// 8 hot (recently seen or back-referenced) objects with optional skip.
	static const int kNumberOfHotObjects = 8;
	STATIC_ASSERT(kNumberOfHotObjects == HotObjectsList::kSize);
	// 0x38..0x3f
	static const int kHotObject = 0x38;
	// 0x58..0x5f
	static const int kHotObjectWithSkip = 0x58;
	static const int kHotObjectMask = 0x07;

	// 0x1f, 0x35..0x37, 0x55..0x57, 0x75..0x7f unused.

	// ---------- byte code range 0x80..0xff ----------
	// First 32 root array items.
	static const int kNumberOfRootArrayConstants = 0x20;
	// 0x80..0x9f
	static const int kRootArrayConstants = 0x80;
	// 0xa0..0xbf
	static const int kRootArrayConstantsWithSkip = 0xa0;
	static const int kRootArrayConstantsMask = 0x1f;

	// 32 common raw data lengths.
	static const int kNumberOfFixedRawData = 0x20;
	// 0xc0..0xdf
	static const int kFixedRawData = 0xc0;
	static const int kOnePointerRawData = kFixedRawData;
	static const int kFixedRawDataStart = kFixedRawData - 1;

	// 16 repeats lengths.
	static const int kNumberOfFixedRepeat = 0x10;
	// 0xe0..0xef
	static const int kFixedRepeat = 0xe0;
	static const int kFixedRepeatStart = kFixedRepeat - 1;

	// 0xf0..0xff unused.

	// ---------- special values ----------
	static const int kAnyOldSpace = -1;

	// Sentinel after a new object to indicate that double alignment is needed.
	static const int kDoubleAlignmentSentinel = 0;

	// ---------- member variable ----------
	HotObjectsList hot_objects_;
	};

	class SerializedData {
	public:
	class Reservation {
	public:
	explicit Reservation(uint32_t size)
	: reservation_(ChunkSizeBits::encode(size)) {}

	uint32_t chunk_size() const { return ChunkSizeBits::decode(reservation_); }
	bool is_last() const { return IsLastChunkBits::decode(reservation_); }

	void mark_as_last() { reservation_ \|= IsLastChunkBits::encode(true); }

	private:
	uint32_t reservation_;
	};

	SerializedData(byte* data, int size)
	: data_(data), size_(size), owns_data_(false) {}
	SerializedData() : data_(NULL), size_(0), owns_data_(false) {}

	~SerializedData() {
	if (owns_data_) DeleteArray<byte>(data_);
	}

	uint32_t GetMagicNumber() const { return GetHeaderValue(kMagicNumberOffset); }

	class ChunkSizeBits : public BitField<uint32_t, 0, 31> {};
	class IsLastChunkBits : public BitField<bool, 31, 1> {};

	static uint32_t ComputeMagicNumber(ExternalReferenceTable* table) {
	uint32_t external_refs = table->size();
	return 0xC0DE0000 ^ external_refs;
	}

	protected:
	void SetHeaderValue(int offset, uint32_t value) {
	uint32_t* address = reinterpret_cast<uint32_t*>(data_ + offset);
	memcpy(reinterpret_cast<uint32_t*>(address), &value, sizeof(value));
	}

	uint32_t GetHeaderValue(int offset) const {
	uint32_t value;
	memcpy(&value, reinterpret_cast<int*>(data_ + offset), sizeof(value));
	return value;
	}

	void AllocateData(int size);

	static uint32_t ComputeMagicNumber(Isolate* isolate) {
	return ComputeMagicNumber(ExternalReferenceTable::instance(isolate));
	}

	void SetMagicNumber(Isolate* isolate) {
	SetHeaderValue(kMagicNumberOffset, ComputeMagicNumber(isolate));
	}

	static const int kMagicNumberOffset = 0;

	byte* data_;
	int size_;
	bool owns_data_;
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_SNAPSHOT_SERIALIZER_COMMON_H_