src/v8/src/ic/stub-cache.h - cobalt - Git at Google

 // Copyright 2012 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_IC_STUB_CACHE_H_
 #define V8_IC_STUB_CACHE_H_

 #include "src/objects/name.h"
 #include "src/objects/tagged-value.h"

 namespace v8 {
 namespace internal {

 // The stub cache is used for megamorphic property accesses.
 // It maps (map, name, type) to property access handlers. The cache does not
 // need explicit invalidation when a prototype chain is modified, since the
 // handlers verify the chain.


 class SCTableReference {
  public:
   Address address() const { return address_; }

  private:
   explicit SCTableReference(Address address) : address_(address) {}

   Address address_;

   friend class StubCache;
 };

 class V8_EXPORT_PRIVATE StubCache {
  public:
   struct Entry {
     // {key} is a tagged Name pointer, may be cleared by setting to empty
     // string.
     StrongTaggedValue key;
     // {value} is a tagged heap object reference (weak or strong), equivalent
     // to a MaybeObject's payload.
     TaggedValue value;
     // {map} is a tagged Map pointer, may be cleared by setting to Smi::zero().
     StrongTaggedValue map;
   };

   void Initialize();
   // Access cache for entry hash(name, map).
   void Set(Name name, Map map, MaybeObject handler);
   MaybeObject Get(Name name, Map map);
   // Clear the lookup table (@ mark compact collection).
   void Clear();

   enum Table { kPrimary, kSecondary };

   SCTableReference key_reference(StubCache::Table table) {
     return SCTableReference(
         reinterpret_cast<Address>(&first_entry(table)->key));
   }

   SCTableReference map_reference(StubCache::Table table) {
     return SCTableReference(
         reinterpret_cast<Address>(&first_entry(table)->map));
   }

   SCTableReference value_reference(StubCache::Table table) {
     return SCTableReference(
         reinterpret_cast<Address>(&first_entry(table)->value));
   }

   StubCache::Entry* first_entry(StubCache::Table table) {
     switch (table) {
       case StubCache::kPrimary:
         return StubCache::primary_;
       case StubCache::kSecondary:
         return StubCache::secondary_;
     }
     UNREACHABLE();
   }

   Isolate* isolate() { return isolate_; }

   // Setting the entry size such that the index is shifted by Name::kHashShift
   // is convenient; shifting down the length field (to extract the hash code)
   // automatically discards the hash bit field.
   static const int kCacheIndexShift = Name::kHashShift;

   static const int kPrimaryTableBits = 11;
   static const int kPrimaryTableSize = (1 << kPrimaryTableBits);
   static const int kSecondaryTableBits = 9;
   static const int kSecondaryTableSize = (1 << kSecondaryTableBits);

   // We compute the hash code for a map as follows:
   //   <code> = <address> ^ (<address> >> kMapKeyShift)
   static const int kMapKeyShift = kPrimaryTableBits + kCacheIndexShift;

   // Some magic number used in the secondary hash computation.
   static const int kSecondaryMagic = 0xb16ca6e5;

   static int PrimaryOffsetForTesting(Name name, Map map);
   static int SecondaryOffsetForTesting(Name name, int seed);

   // The constructor is made public only for the purposes of testing.
   explicit StubCache(Isolate* isolate);

  private:
   // The stub cache has a primary and secondary level.  The two levels have
   // different hashing algorithms in order to avoid simultaneous collisions
   // in both caches.  Unlike a probing strategy (quadratic or otherwise) the
   // update strategy on updates is fairly clear and simple:  Any existing entry
   // in the primary cache is moved to the secondary cache, and secondary cache
   // entries are overwritten.

   // Hash algorithm for the primary table.  This algorithm is replicated in
   // assembler for every architecture.  Returns an index into the table that
   // is scaled by 1 << kCacheIndexShift.
   static int PrimaryOffset(Name name, Map map);

   // Hash algorithm for the secondary table.  This algorithm is replicated in
   // assembler for every architecture.  Returns an index into the table that
   // is scaled by 1 << kCacheIndexShift.
   static int SecondaryOffset(Name name, int seed);

   // Compute the entry for a given offset in exactly the same way as
   // we do in generated code.  We generate an hash code that already
   // ends in Name::kHashShift 0s.  Then we multiply it so it is a multiple
   // of sizeof(Entry).  This makes it easier to avoid making mistakes
   // in the hashed offset computations.
   static Entry* entry(Entry* table, int offset) {
     const int multiplier = sizeof(*table) >> Name::kHashShift;
     return reinterpret_cast<Entry*>(reinterpret_cast<Address>(table) +
                                     offset * multiplier);
   }

  private:
   Entry primary_[kPrimaryTableSize];
   Entry secondary_[kSecondaryTableSize];
   Isolate* isolate_;

   friend class Isolate;
   friend class SCTableReference;

   DISALLOW_COPY_AND_ASSIGN(StubCache);
 };
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_IC_STUB_CACHE_H_
	// Copyright 2012 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_IC_STUB_CACHE_H_
	#define V8_IC_STUB_CACHE_H_

	#include "src/objects/name.h"
	#include "src/objects/tagged-value.h"

	namespace v8 {
	namespace internal {

	// The stub cache is used for megamorphic property accesses.
	// It maps (map, name, type) to property access handlers. The cache does not
	// need explicit invalidation when a prototype chain is modified, since the
	// handlers verify the chain.


	class SCTableReference {
	public:
	Address address() const { return address_; }

	private:
	explicit SCTableReference(Address address) : address_(address) {}

	Address address_;

	friend class StubCache;
	};

	class V8_EXPORT_PRIVATE StubCache {
	public:
	struct Entry {
	// {key} is a tagged Name pointer, may be cleared by setting to empty
	// string.
	StrongTaggedValue key;
	// {value} is a tagged heap object reference (weak or strong), equivalent
	// to a MaybeObject's payload.
	TaggedValue value;
	// {map} is a tagged Map pointer, may be cleared by setting to Smi::zero().
	StrongTaggedValue map;
	};

	void Initialize();
	// Access cache for entry hash(name, map).
	void Set(Name name, Map map, MaybeObject handler);
	MaybeObject Get(Name name, Map map);
	// Clear the lookup table (@ mark compact collection).
	void Clear();

	enum Table { kPrimary, kSecondary };

	SCTableReference key_reference(StubCache::Table table) {
	return SCTableReference(
	reinterpret_cast<Address>(&first_entry(table)->key));
	}

	SCTableReference map_reference(StubCache::Table table) {
	return SCTableReference(
	reinterpret_cast<Address>(&first_entry(table)->map));
	}

	SCTableReference value_reference(StubCache::Table table) {
	return SCTableReference(
	reinterpret_cast<Address>(&first_entry(table)->value));
	}

	StubCache::Entry* first_entry(StubCache::Table table) {
	switch (table) {
	case StubCache::kPrimary:
	return StubCache::primary_;
	case StubCache::kSecondary:
	return StubCache::secondary_;
	}
	UNREACHABLE();
	}

	Isolate* isolate() { return isolate_; }

	// Setting the entry size such that the index is shifted by Name::kHashShift
	// is convenient; shifting down the length field (to extract the hash code)
	// automatically discards the hash bit field.
	static const int kCacheIndexShift = Name::kHashShift;

	static const int kPrimaryTableBits = 11;
	static const int kPrimaryTableSize = (1 << kPrimaryTableBits);
	static const int kSecondaryTableBits = 9;
	static const int kSecondaryTableSize = (1 << kSecondaryTableBits);

	// We compute the hash code for a map as follows:
	// <code> = <address> ^ (<address> >> kMapKeyShift)
	static const int kMapKeyShift = kPrimaryTableBits + kCacheIndexShift;

	// Some magic number used in the secondary hash computation.
	static const int kSecondaryMagic = 0xb16ca6e5;

	static int PrimaryOffsetForTesting(Name name, Map map);
	static int SecondaryOffsetForTesting(Name name, int seed);

	// The constructor is made public only for the purposes of testing.
	explicit StubCache(Isolate* isolate);

	private:
	// The stub cache has a primary and secondary level. The two levels have
	// different hashing algorithms in order to avoid simultaneous collisions
	// in both caches. Unlike a probing strategy (quadratic or otherwise) the
	// update strategy on updates is fairly clear and simple: Any existing entry
	// in the primary cache is moved to the secondary cache, and secondary cache
	// entries are overwritten.

	// Hash algorithm for the primary table. This algorithm is replicated in
	// assembler for every architecture. Returns an index into the table that
	// is scaled by 1 << kCacheIndexShift.
	static int PrimaryOffset(Name name, Map map);

	// Hash algorithm for the secondary table. This algorithm is replicated in
	// assembler for every architecture. Returns an index into the table that
	// is scaled by 1 << kCacheIndexShift.
	static int SecondaryOffset(Name name, int seed);

	// Compute the entry for a given offset in exactly the same way as
	// we do in generated code. We generate an hash code that already
	// ends in Name::kHashShift 0s. Then we multiply it so it is a multiple
	// of sizeof(Entry). This makes it easier to avoid making mistakes
	// in the hashed offset computations.
	static Entry* entry(Entry* table, int offset) {
	const int multiplier = sizeof(*table) >> Name::kHashShift;
	return reinterpret_cast<Entry*>(reinterpret_cast<Address>(table) +
	offset * multiplier);
	}

	private:
	Entry primary_[kPrimaryTableSize];
	Entry secondary_[kSecondaryTableSize];
	Isolate* isolate_;

	friend class Isolate;
	friend class SCTableReference;

	DISALLOW_COPY_AND_ASSIGN(StubCache);
	};
	} // namespace internal
	} // namespace v8

	#endif // V8_IC_STUB_CACHE_H_