jsoncpp/src/lib_json/json_internalmap.inl - nest-cam/4320010/jsoncpp - Git at Google

 // Copyright 2007-2010 Baptiste Lepilleur
 // Distributed under MIT license, or public domain if desired and
 // recognized in your jurisdiction.
 // See file LICENSE for detail or copy at http://jsoncpp.sourceforge.net/LICENSE

 // included by json_value.cpp

 namespace Json {

 // //////////////////////////////////////////////////////////////////
 // //////////////////////////////////////////////////////////////////
 // //////////////////////////////////////////////////////////////////
 // class ValueInternalMap
 // //////////////////////////////////////////////////////////////////
 // //////////////////////////////////////////////////////////////////
 // //////////////////////////////////////////////////////////////////

 /** \internal MUST be safely initialized using memset( this, 0, sizeof(ValueInternalLink) );
    * This optimization is used by the fast allocator.
    */
 ValueInternalLink::ValueInternalLink()
    : previous_( 0 )
    , next_( 0 )
 {
 }

 ValueInternalLink::~ValueInternalLink()
 {
    for ( int index =0; index < itemPerLink; ++index )
    {
       if ( !items_[index].isItemAvailable() )
       {
          if ( !items_[index].isMemberNameStatic() )
             free( keys_[index] );
       }
       else
          break;
    }
 }


 ValueMapAllocator::~ValueMapAllocator()
 {
 }

 #ifdef JSON_USE_SIMPLE_INTERNAL_ALLOCATOR
 class DefaultValueMapAllocator : public ValueMapAllocator
 {
 public: // overridden from ValueMapAllocator
    virtual ValueInternalMap *newMap()
    {
       return new ValueInternalMap();
    }

    virtual ValueInternalMap *newMapCopy( const ValueInternalMap &other )
    {
       return new ValueInternalMap( other );
    }

    virtual void destructMap( ValueInternalMap *map )
    {
       delete map;
    }

    virtual ValueInternalLink *allocateMapBuckets( unsigned int size )
    {
       return new ValueInternalLink[size];
    }

    virtual void releaseMapBuckets( ValueInternalLink *links )
    {
       delete [] links;
    }

    virtual ValueInternalLink *allocateMapLink()
    {
       return new ValueInternalLink();
    }

    virtual void releaseMapLink( ValueInternalLink *link )
    {
       delete link;
    }
 };
 #else
 /// @todo make this thread-safe (lock when accessign batch allocator)
 class DefaultValueMapAllocator : public ValueMapAllocator
 {
 public: // overridden from ValueMapAllocator
    virtual ValueInternalMap *newMap()
    {
       ValueInternalMap *map = mapsAllocator_.allocate();
       new (map) ValueInternalMap(); // placement new
       return map;
    }

    virtual ValueInternalMap *newMapCopy( const ValueInternalMap &other )
    {
       ValueInternalMap *map = mapsAllocator_.allocate();
       new (map) ValueInternalMap( other ); // placement new
       return map;
    }

    virtual void destructMap( ValueInternalMap *map )
    {
       if ( map )
       {
          map->~ValueInternalMap();
          mapsAllocator_.release( map );
       }
    }

    virtual ValueInternalLink *allocateMapBuckets( unsigned int size )
    {
       return new ValueInternalLink[size];
    }

    virtual void releaseMapBuckets( ValueInternalLink *links )
    {
       delete [] links;
    }

    virtual ValueInternalLink *allocateMapLink()
    {
       ValueInternalLink *link = linksAllocator_.allocate();
       memset( link, 0, sizeof(ValueInternalLink) );
       return link;
    }

    virtual void releaseMapLink( ValueInternalLink *link )
    {
       link->~ValueInternalLink();
       linksAllocator_.release( link );
    }
 private:
    BatchAllocator<ValueInternalMap,1> mapsAllocator_;
    BatchAllocator<ValueInternalLink,1> linksAllocator_;
 };
 #endif

 static ValueMapAllocator *&mapAllocator()
 {
    static DefaultValueMapAllocator defaultAllocator;
    static ValueMapAllocator *mapAllocator = &defaultAllocator;
    return mapAllocator;
 }

 static struct DummyMapAllocatorInitializer {
    DummyMapAllocatorInitializer()
    {
       mapAllocator();      // ensure mapAllocator() statics are initialized before main().
    }
 } dummyMapAllocatorInitializer;


 // h(K) = value * K >> w ; with w = 32 & K prime w.r.t. 2^32.

 /*
 use linked list hash map.
 buckets array is a container.
 linked list element contains 6 key/values. (memory = (16+4) * 6 + 4 = 124)
 value have extra state: valid, available, deleted
 */


 ValueInternalMap::ValueInternalMap()
    : buckets_( 0 )
    , tailLink_( 0 )
    , bucketsSize_( 0 )
    , itemCount_( 0 )
 {
 }


 ValueInternalMap::ValueInternalMap( const ValueInternalMap &other )
    : buckets_( 0 )
    , tailLink_( 0 )
    , bucketsSize_( 0 )
    , itemCount_( 0 )
 {
    reserve( other.itemCount_ );
    IteratorState it;
    IteratorState itEnd;
    other.makeBeginIterator( it );
    other.makeEndIterator( itEnd );
    for ( ; !equals(it,itEnd); increment(it) )
    {
       bool isStatic;
       const char *memberName = key( it, isStatic );
       const Value &aValue = value( it );
       resolveReference(memberName, isStatic) = aValue;
    }
 }


 ValueInternalMap &
 ValueInternalMap::operator =( const ValueInternalMap &other )
 {
    ValueInternalMap dummy( other );
    swap( dummy );
    return *this;
 }


 ValueInternalMap::~ValueInternalMap()
 {
    if ( buckets_ )
    {
       for ( BucketIndex bucketIndex =0; bucketIndex < bucketsSize_; ++bucketIndex )
       {
          ValueInternalLink *link = buckets_[bucketIndex].next_;
          while ( link )
          {
             ValueInternalLink *linkToRelease = link;
             link = link->next_;
             mapAllocator()->releaseMapLink( linkToRelease );
          }
       }
       mapAllocator()->releaseMapBuckets( buckets_ );
    }
 }


 void
 ValueInternalMap::swap( ValueInternalMap &other )
 {
    ValueInternalLink *tempBuckets = buckets_;
    buckets_ = other.buckets_;
    other.buckets_ = tempBuckets;
    ValueInternalLink *tempTailLink = tailLink_;
    tailLink_ = other.tailLink_;
    other.tailLink_ = tempTailLink;
    BucketIndex tempBucketsSize = bucketsSize_;
    bucketsSize_ = other.bucketsSize_;
    other.bucketsSize_ = tempBucketsSize;
    BucketIndex tempItemCount = itemCount_;
    itemCount_ = other.itemCount_;
    other.itemCount_ = tempItemCount;
 }


 void
 ValueInternalMap::clear()
 {
    ValueInternalMap dummy;
    swap( dummy );
 }


 ValueInternalMap::BucketIndex
 ValueInternalMap::size() const
 {
    return itemCount_;
 }

 bool
 ValueInternalMap::reserveDelta( BucketIndex growth )
 {
    return reserve( itemCount_ + growth );
 }

 bool
 ValueInternalMap::reserve( BucketIndex newItemCount )
 {
    if ( !buckets_  &&  newItemCount > 0 )
    {
       buckets_ = mapAllocator()->allocateMapBuckets( 1 );
       bucketsSize_ = 1;
       tailLink_ = &buckets_[0];
    }
 //   BucketIndex idealBucketCount = (newItemCount + ValueInternalLink::itemPerLink) / ValueInternalLink::itemPerLink;
    return true;
 }


 const Value *
 ValueInternalMap::find( const char *key ) const
 {
    if ( !bucketsSize_ )
       return 0;
    HashKey hashedKey = hash( key );
    BucketIndex bucketIndex = hashedKey % bucketsSize_;
    for ( const ValueInternalLink *current = &buckets_[bucketIndex];
          current != 0;
          current = current->next_ )
    {
       for ( BucketIndex index=0; index < ValueInternalLink::itemPerLink; ++index )
       {
          if ( current->items_[index].isItemAvailable() )
             return 0;
          if ( strcmp( key, current->keys_[index] ) == 0 )
             return &current->items_[index];
       }
    }
    return 0;
 }


 Value *
 ValueInternalMap::find( const char *key )
 {
    const ValueInternalMap *constThis = this;
    return const_cast<Value *>( constThis->find( key ) );
 }


 Value &
 ValueInternalMap::resolveReference( const char *key,
                                     bool isStatic )
 {
    HashKey hashedKey = hash( key );
    if ( bucketsSize_ )
    {
       BucketIndex bucketIndex = hashedKey % bucketsSize_;
       ValueInternalLink **previous = 0;
       BucketIndex index;
       for ( ValueInternalLink *current = &buckets_[bucketIndex];
             current != 0;
             previous = &current->next_, current = current->next_ )
       {
          for ( index=0; index < ValueInternalLink::itemPerLink; ++index )
          {
             if ( current->items_[index].isItemAvailable() )
                return setNewItem( key, isStatic, current, index );
             if ( strcmp( key, current->keys_[index] ) == 0 )
                return current->items_[index];
          }
       }
    }

    reserveDelta( 1 );
    return unsafeAdd( key, isStatic, hashedKey );
 }


 void
 ValueInternalMap::remove( const char *key )
 {
    HashKey hashedKey = hash( key );
    if ( !bucketsSize_ )
       return;
    BucketIndex bucketIndex = hashedKey % bucketsSize_;
    for ( ValueInternalLink *link = &buckets_[bucketIndex];
          link != 0;
          link = link->next_ )
    {
       BucketIndex index;
       for ( index =0; index < ValueInternalLink::itemPerLink; ++index )
       {
          if ( link->items_[index].isItemAvailable() )
             return;
          if ( strcmp( key, link->keys_[index] ) == 0 )
          {
             doActualRemove( link, index, bucketIndex );
             return;
          }
       }
    }
 }

 void
 ValueInternalMap::doActualRemove( ValueInternalLink *link,
                                   BucketIndex index,
                                   BucketIndex bucketIndex )
 {
    // find last item of the bucket and swap it with the 'removed' one.
    // set removed items flags to 'available'.
    // if last page only contains 'available' items, then desallocate it (it's empty)
    ValueInternalLink *&lastLink = getLastLinkInBucket( index );
    BucketIndex lastItemIndex = 1; // a link can never be empty, so start at 1
    for ( ;
          lastItemIndex < ValueInternalLink::itemPerLink;
          ++lastItemIndex ) // may be optimized with dicotomic search
    {
       if ( lastLink->items_[lastItemIndex].isItemAvailable() )
          break;
    }

    BucketIndex lastUsedIndex = lastItemIndex - 1;
    Value *valueToDelete = &link->items_[index];
    Value *valueToPreserve = &lastLink->items_[lastUsedIndex];
    if ( valueToDelete != valueToPreserve )
       valueToDelete->swap( *valueToPreserve );
    if ( lastUsedIndex == 0 )  // page is now empty
    {  // remove it from bucket linked list and delete it.
       ValueInternalLink *linkPreviousToLast = lastLink->previous_;
       if ( linkPreviousToLast != 0 )   // can not deleted bucket link.
       {
          mapAllocator()->releaseMapLink( lastLink );
          linkPreviousToLast->next_ = 0;
          lastLink = linkPreviousToLast;
       }
    }
    else
    {
       Value dummy;
       valueToPreserve->swap( dummy ); // restore deleted to default Value.
       valueToPreserve->setItemUsed( false );
    }
    --itemCount_;
 }


 ValueInternalLink *&
 ValueInternalMap::getLastLinkInBucket( BucketIndex bucketIndex )
 {
    if ( bucketIndex == bucketsSize_ - 1 )
       return tailLink_;
    ValueInternalLink *&previous = buckets_[bucketIndex+1].previous_;
    if ( !previous )
       previous = &buckets_[bucketIndex];
    return previous;
 }


 Value &
 ValueInternalMap::setNewItem( const char *key,
                               bool isStatic,
                               ValueInternalLink *link,
                               BucketIndex index )
 {
    char *duplicatedKey = makeMemberName( key );
    ++itemCount_;
    link->keys_[index] = duplicatedKey;
    link->items_[index].setItemUsed();
    link->items_[index].setMemberNameIsStatic( isStatic );
    return link->items_[index]; // items already default constructed.
 }


 Value &
 ValueInternalMap::unsafeAdd( const char *key,
                              bool isStatic,
                              HashKey hashedKey )
 {
    JSON_ASSERT_MESSAGE( bucketsSize_ > 0, "ValueInternalMap::unsafeAdd(): internal logic error." );
    BucketIndex bucketIndex = hashedKey % bucketsSize_;
    ValueInternalLink *&previousLink = getLastLinkInBucket( bucketIndex );
    ValueInternalLink *link = previousLink;
    BucketIndex index;
    for ( index =0; index < ValueInternalLink::itemPerLink; ++index )
    {
       if ( link->items_[index].isItemAvailable() )
          break;
    }
    if ( index == ValueInternalLink::itemPerLink ) // need to add a new page
    {
       ValueInternalLink *newLink = mapAllocator()->allocateMapLink();
       index = 0;
       link->next_ = newLink;
       previousLink = newLink;
       link = newLink;
    }
    return setNewItem( key, isStatic, link, index );
 }


 ValueInternalMap::HashKey
 ValueInternalMap::hash( const char *key ) const
 {
    HashKey hash = 0;
    while ( *key )
       hash += *key++ * 37;
    return hash;
 }


 int
 ValueInternalMap::compare( const ValueInternalMap &other ) const
 {
    int sizeDiff( itemCount_ - other.itemCount_ );
    if ( sizeDiff != 0 )
       return sizeDiff;
    // Strict order guaranty is required. Compare all keys FIRST, then compare values.
    IteratorState it;
    IteratorState itEnd;
    makeBeginIterator( it );
    makeEndIterator( itEnd );
    for ( ; !equals(it,itEnd); increment(it) )
    {
       if ( !other.find( key( it ) ) )
          return 1;
    }

    // All keys are equals, let's compare values
    makeBeginIterator( it );
    for ( ; !equals(it,itEnd); increment(it) )
    {
       const Value *otherValue = other.find( key( it ) );
       int valueDiff = value(it).compare( *otherValue );
       if ( valueDiff != 0 )
          return valueDiff;
    }
    return 0;
 }


 void
 ValueInternalMap::makeBeginIterator( IteratorState &it ) const
 {
    it.map_ = const_cast<ValueInternalMap *>( this );
    it.bucketIndex_ = 0;
    it.itemIndex_ = 0;
    it.link_ = buckets_;
 }


 void
 ValueInternalMap::makeEndIterator( IteratorState &it ) const
 {
    it.map_ = const_cast<ValueInternalMap *>( this );
    it.bucketIndex_ = bucketsSize_;
    it.itemIndex_ = 0;
    it.link_ = 0;
 }


 bool
 ValueInternalMap::equals( const IteratorState &x, const IteratorState &other )
 {
    return x.map_ == other.map_
           &&  x.bucketIndex_ == other.bucketIndex_
           &&  x.link_ == other.link_
           &&  x.itemIndex_ == other.itemIndex_;
 }


 void
 ValueInternalMap::incrementBucket( IteratorState &iterator )
 {
    ++iterator.bucketIndex_;
    JSON_ASSERT_MESSAGE( iterator.bucketIndex_ <= iterator.map_->bucketsSize_,
       "ValueInternalMap::increment(): attempting to iterate beyond end." );
    if ( iterator.bucketIndex_ == iterator.map_->bucketsSize_ )
       iterator.link_ = 0;
    else
       iterator.link_ = &(iterator.map_->buckets_[iterator.bucketIndex_]);
    iterator.itemIndex_ = 0;
 }


 void
 ValueInternalMap::increment( IteratorState &iterator )
 {
    JSON_ASSERT_MESSAGE( iterator.map_, "Attempting to iterator using invalid iterator." );
    ++iterator.itemIndex_;
    if ( iterator.itemIndex_ == ValueInternalLink::itemPerLink )
    {
       JSON_ASSERT_MESSAGE( iterator.link_ != 0,
          "ValueInternalMap::increment(): attempting to iterate beyond end." );
       iterator.link_ = iterator.link_->next_;
       if ( iterator.link_ == 0 )
          incrementBucket( iterator );
    }
    else if ( iterator.link_->items_[iterator.itemIndex_].isItemAvailable() )
    {
       incrementBucket( iterator );
    }
 }


 void
 ValueInternalMap::decrement( IteratorState &iterator )
 {
    if ( iterator.itemIndex_ == 0 )
    {
       JSON_ASSERT_MESSAGE( iterator.map_, "Attempting to iterate using invalid iterator." );
       if ( iterator.link_ == &iterator.map_->buckets_[iterator.bucketIndex_] )
       {
          JSON_ASSERT_MESSAGE( iterator.bucketIndex_ > 0, "Attempting to iterate beyond beginning." );
          --(iterator.bucketIndex_);
       }
       iterator.link_ = iterator.link_->previous_;
       iterator.itemIndex_ = ValueInternalLink::itemPerLink - 1;
    }
 }


 const char *
 ValueInternalMap::key( const IteratorState &iterator )
 {
    JSON_ASSERT_MESSAGE( iterator.link_, "Attempting to iterate using invalid iterator." );
    return iterator.link_->keys_[iterator.itemIndex_];
 }

 const char *
 ValueInternalMap::key( const IteratorState &iterator, bool &isStatic )
 {
    JSON_ASSERT_MESSAGE( iterator.link_, "Attempting to iterate using invalid iterator." );
    isStatic = iterator.link_->items_[iterator.itemIndex_].isMemberNameStatic();
    return iterator.link_->keys_[iterator.itemIndex_];
 }


 Value &
 ValueInternalMap::value( const IteratorState &iterator )
 {
    JSON_ASSERT_MESSAGE( iterator.link_, "Attempting to iterate using invalid iterator." );
    return iterator.link_->items_[iterator.itemIndex_];
 }


 int
 ValueInternalMap::distance( const IteratorState &x, const IteratorState &y )
 {
    int offset = 0;
    IteratorState it = x;
    while ( !equals( it, y ) )
       increment( it );
    return offset;
 }

 } // namespace Json
	// Copyright 2007-2010 Baptiste Lepilleur
	// Distributed under MIT license, or public domain if desired and
	// recognized in your jurisdiction.
	// See file LICENSE for detail or copy at http://jsoncpp.sourceforge.net/LICENSE

	// included by json_value.cpp

	namespace Json {

	// //////////////////////////////////////////////////////////////////
	// //////////////////////////////////////////////////////////////////
	// //////////////////////////////////////////////////////////////////
	// class ValueInternalMap
	// //////////////////////////////////////////////////////////////////
	// //////////////////////////////////////////////////////////////////
	// //////////////////////////////////////////////////////////////////

	/** \internal MUST be safely initialized using memset( this, 0, sizeof(ValueInternalLink) );
	* This optimization is used by the fast allocator.
	*/
	ValueInternalLink::ValueInternalLink()
	: previous_( 0 )
	, next_( 0 )
	{
	}

	ValueInternalLink::~ValueInternalLink()
	{
	for ( int index =0; index < itemPerLink; ++index )
	{
	if ( !items_[index].isItemAvailable() )
	{
	if ( !items_[index].isMemberNameStatic() )
	free( keys_[index] );
	}
	else
	break;
	}
	}



	ValueMapAllocator::~ValueMapAllocator()
	{
	}

	#ifdef JSON_USE_SIMPLE_INTERNAL_ALLOCATOR
	class DefaultValueMapAllocator : public ValueMapAllocator
	{
	public: // overridden from ValueMapAllocator
	virtual ValueInternalMap *newMap()
	{
	return new ValueInternalMap();
	}

	virtual ValueInternalMap *newMapCopy( const ValueInternalMap &other )
	{
	return new ValueInternalMap( other );
	}

	virtual void destructMap( ValueInternalMap *map )
	{
	delete map;
	}

	virtual ValueInternalLink *allocateMapBuckets( unsigned int size )
	{
	return new ValueInternalLink[size];
	}

	virtual void releaseMapBuckets( ValueInternalLink *links )
	{
	delete [] links;
	}

	virtual ValueInternalLink *allocateMapLink()
	{
	return new ValueInternalLink();
	}

	virtual void releaseMapLink( ValueInternalLink *link )
	{
	delete link;
	}
	};
	#else
	/// @todo make this thread-safe (lock when accessign batch allocator)
	class DefaultValueMapAllocator : public ValueMapAllocator
	{
	public: // overridden from ValueMapAllocator
	virtual ValueInternalMap *newMap()
	{
	ValueInternalMap *map = mapsAllocator_.allocate();
	new (map) ValueInternalMap(); // placement new
	return map;
	}

	virtual ValueInternalMap *newMapCopy( const ValueInternalMap &other )
	{
	ValueInternalMap *map = mapsAllocator_.allocate();
	new (map) ValueInternalMap( other ); // placement new
	return map;
	}

	virtual void destructMap( ValueInternalMap *map )
	{
	if ( map )
	{
	map->~ValueInternalMap();
	mapsAllocator_.release( map );
	}
	}

	virtual ValueInternalLink *allocateMapBuckets( unsigned int size )
	{
	return new ValueInternalLink[size];
	}

	virtual void releaseMapBuckets( ValueInternalLink *links )
	{
	delete [] links;
	}

	virtual ValueInternalLink *allocateMapLink()
	{
	ValueInternalLink *link = linksAllocator_.allocate();
	memset( link, 0, sizeof(ValueInternalLink) );
	return link;
	}

	virtual void releaseMapLink( ValueInternalLink *link )
	{
	link->~ValueInternalLink();
	linksAllocator_.release( link );
	}
	private:
	BatchAllocator<ValueInternalMap,1> mapsAllocator_;
	BatchAllocator<ValueInternalLink,1> linksAllocator_;
	};
	#endif

	static ValueMapAllocator *&mapAllocator()
	{
	static DefaultValueMapAllocator defaultAllocator;
	static ValueMapAllocator *mapAllocator = &defaultAllocator;
	return mapAllocator;
	}

	static struct DummyMapAllocatorInitializer {
	DummyMapAllocatorInitializer()
	{
	mapAllocator(); // ensure mapAllocator() statics are initialized before main().
	}
	} dummyMapAllocatorInitializer;



	// h(K) = value * K >> w ; with w = 32 & K prime w.r.t. 2^32.

	/*
	use linked list hash map.
	buckets array is a container.
	linked list element contains 6 key/values. (memory = (16+4) * 6 + 4 = 124)
	value have extra state: valid, available, deleted
	*/


	ValueInternalMap::ValueInternalMap()
	: buckets_( 0 )
	, tailLink_( 0 )
	, bucketsSize_( 0 )
	, itemCount_( 0 )
	{
	}


	ValueInternalMap::ValueInternalMap( const ValueInternalMap &other )
	: buckets_( 0 )
	, tailLink_( 0 )
	, bucketsSize_( 0 )
	, itemCount_( 0 )
	{
	reserve( other.itemCount_ );
	IteratorState it;
	IteratorState itEnd;
	other.makeBeginIterator( it );
	other.makeEndIterator( itEnd );
	for ( ; !equals(it,itEnd); increment(it) )
	{
	bool isStatic;
	const char *memberName = key( it, isStatic );
	const Value &aValue = value( it );
	resolveReference(memberName, isStatic) = aValue;
	}
	}


	ValueInternalMap &
	ValueInternalMap::operator =( const ValueInternalMap &other )
	{
	ValueInternalMap dummy( other );
	swap( dummy );
	return *this;
	}


	ValueInternalMap::~ValueInternalMap()
	{
	if ( buckets_ )
	{
	for ( BucketIndex bucketIndex =0; bucketIndex < bucketsSize_; ++bucketIndex )
	{
	ValueInternalLink *link = buckets_[bucketIndex].next_;
	while ( link )
	{
	ValueInternalLink *linkToRelease = link;
	link = link->next_;
	mapAllocator()->releaseMapLink( linkToRelease );
	}
	}
	mapAllocator()->releaseMapBuckets( buckets_ );
	}
	}


	void
	ValueInternalMap::swap( ValueInternalMap &other )
	{
	ValueInternalLink *tempBuckets = buckets_;
	buckets_ = other.buckets_;
	other.buckets_ = tempBuckets;
	ValueInternalLink *tempTailLink = tailLink_;
	tailLink_ = other.tailLink_;
	other.tailLink_ = tempTailLink;
	BucketIndex tempBucketsSize = bucketsSize_;
	bucketsSize_ = other.bucketsSize_;
	other.bucketsSize_ = tempBucketsSize;
	BucketIndex tempItemCount = itemCount_;
	itemCount_ = other.itemCount_;
	other.itemCount_ = tempItemCount;
	}


	void
	ValueInternalMap::clear()
	{
	ValueInternalMap dummy;
	swap( dummy );
	}


	ValueInternalMap::BucketIndex
	ValueInternalMap::size() const
	{
	return itemCount_;
	}

	bool
	ValueInternalMap::reserveDelta( BucketIndex growth )
	{
	return reserve( itemCount_ + growth );
	}

	bool
	ValueInternalMap::reserve( BucketIndex newItemCount )
	{
	if ( !buckets_ && newItemCount > 0 )
	{
	buckets_ = mapAllocator()->allocateMapBuckets( 1 );
	bucketsSize_ = 1;
	tailLink_ = &buckets_[0];
	}
	// BucketIndex idealBucketCount = (newItemCount + ValueInternalLink::itemPerLink) / ValueInternalLink::itemPerLink;
	return true;
	}


	const Value *
	ValueInternalMap::find( const char *key ) const
	{
	if ( !bucketsSize_ )
	return 0;
	HashKey hashedKey = hash( key );
	BucketIndex bucketIndex = hashedKey % bucketsSize_;
	for ( const ValueInternalLink *current = &buckets_[bucketIndex];
	current != 0;
	current = current->next_ )
	{
	for ( BucketIndex index=0; index < ValueInternalLink::itemPerLink; ++index )
	{
	if ( current->items_[index].isItemAvailable() )
	return 0;
	if ( strcmp( key, current->keys_[index] ) == 0 )
	return &current->items_[index];
	}
	}
	return 0;
	}


	Value *
	ValueInternalMap::find( const char *key )
	{
	const ValueInternalMap *constThis = this;
	return const_cast<Value *>( constThis->find( key ) );
	}


	Value &
	ValueInternalMap::resolveReference( const char *key,
	bool isStatic )
	{
	HashKey hashedKey = hash( key );
	if ( bucketsSize_ )
	{
	BucketIndex bucketIndex = hashedKey % bucketsSize_;
	ValueInternalLink **previous = 0;
	BucketIndex index;
	for ( ValueInternalLink *current = &buckets_[bucketIndex];
	current != 0;
	previous = &current->next_, current = current->next_ )
	{
	for ( index=0; index < ValueInternalLink::itemPerLink; ++index )
	{
	if ( current->items_[index].isItemAvailable() )
	return setNewItem( key, isStatic, current, index );
	if ( strcmp( key, current->keys_[index] ) == 0 )
	return current->items_[index];
	}
	}
	}

	reserveDelta( 1 );
	return unsafeAdd( key, isStatic, hashedKey );
	}


	void
	ValueInternalMap::remove( const char *key )
	{
	HashKey hashedKey = hash( key );
	if ( !bucketsSize_ )
	return;
	BucketIndex bucketIndex = hashedKey % bucketsSize_;
	for ( ValueInternalLink *link = &buckets_[bucketIndex];
	link != 0;
	link = link->next_ )
	{
	BucketIndex index;
	for ( index =0; index < ValueInternalLink::itemPerLink; ++index )
	{
	if ( link->items_[index].isItemAvailable() )
	return;
	if ( strcmp( key, link->keys_[index] ) == 0 )
	{
	doActualRemove( link, index, bucketIndex );
	return;
	}
	}
	}
	}

	void
	ValueInternalMap::doActualRemove( ValueInternalLink *link,
	BucketIndex index,
	BucketIndex bucketIndex )
	{
	// find last item of the bucket and swap it with the 'removed' one.
	// set removed items flags to 'available'.
	// if last page only contains 'available' items, then desallocate it (it's empty)
	ValueInternalLink *&lastLink = getLastLinkInBucket( index );
	BucketIndex lastItemIndex = 1; // a link can never be empty, so start at 1
	for ( ;
	lastItemIndex < ValueInternalLink::itemPerLink;
	++lastItemIndex ) // may be optimized with dicotomic search
	{
	if ( lastLink->items_[lastItemIndex].isItemAvailable() )
	break;
	}

	BucketIndex lastUsedIndex = lastItemIndex - 1;
	Value *valueToDelete = &link->items_[index];
	Value *valueToPreserve = &lastLink->items_[lastUsedIndex];
	if ( valueToDelete != valueToPreserve )
	valueToDelete->swap( *valueToPreserve );
	if ( lastUsedIndex == 0 ) // page is now empty
	{ // remove it from bucket linked list and delete it.
	ValueInternalLink *linkPreviousToLast = lastLink->previous_;
	if ( linkPreviousToLast != 0 ) // can not deleted bucket link.
	{
	mapAllocator()->releaseMapLink( lastLink );
	linkPreviousToLast->next_ = 0;
	lastLink = linkPreviousToLast;
	}
	}
	else
	{
	Value dummy;
	valueToPreserve->swap( dummy ); // restore deleted to default Value.
	valueToPreserve->setItemUsed( false );
	}
	--itemCount_;
	}


	ValueInternalLink *&
	ValueInternalMap::getLastLinkInBucket( BucketIndex bucketIndex )
	{
	if ( bucketIndex == bucketsSize_ - 1 )
	return tailLink_;
	ValueInternalLink *&previous = buckets_[bucketIndex+1].previous_;
	if ( !previous )
	previous = &buckets_[bucketIndex];
	return previous;
	}


	Value &
	ValueInternalMap::setNewItem( const char *key,
	bool isStatic,
	ValueInternalLink *link,
	BucketIndex index )
	{
	char *duplicatedKey = makeMemberName( key );
	++itemCount_;
	link->keys_[index] = duplicatedKey;
	link->items_[index].setItemUsed();
	link->items_[index].setMemberNameIsStatic( isStatic );
	return link->items_[index]; // items already default constructed.
	}


	Value &
	ValueInternalMap::unsafeAdd( const char *key,
	bool isStatic,
	HashKey hashedKey )
	{
	JSON_ASSERT_MESSAGE( bucketsSize_ > 0, "ValueInternalMap::unsafeAdd(): internal logic error." );
	BucketIndex bucketIndex = hashedKey % bucketsSize_;
	ValueInternalLink *&previousLink = getLastLinkInBucket( bucketIndex );
	ValueInternalLink *link = previousLink;
	BucketIndex index;
	for ( index =0; index < ValueInternalLink::itemPerLink; ++index )
	{
	if ( link->items_[index].isItemAvailable() )
	break;
	}
	if ( index == ValueInternalLink::itemPerLink ) // need to add a new page
	{
	ValueInternalLink *newLink = mapAllocator()->allocateMapLink();
	index = 0;
	link->next_ = newLink;
	previousLink = newLink;
	link = newLink;
	}
	return setNewItem( key, isStatic, link, index );
	}


	ValueInternalMap::HashKey
	ValueInternalMap::hash( const char *key ) const
	{
	HashKey hash = 0;
	while ( *key )
	hash += key++ 37;
	return hash;
	}


	int
	ValueInternalMap::compare( const ValueInternalMap &other ) const
	{
	int sizeDiff( itemCount_ - other.itemCount_ );
	if ( sizeDiff != 0 )
	return sizeDiff;
	// Strict order guaranty is required. Compare all keys FIRST, then compare values.
	IteratorState it;
	IteratorState itEnd;
	makeBeginIterator( it );
	makeEndIterator( itEnd );
	for ( ; !equals(it,itEnd); increment(it) )
	{
	if ( !other.find( key( it ) ) )
	return 1;
	}

	// All keys are equals, let's compare values
	makeBeginIterator( it );
	for ( ; !equals(it,itEnd); increment(it) )
	{
	const Value *otherValue = other.find( key( it ) );
	int valueDiff = value(it).compare( *otherValue );
	if ( valueDiff != 0 )
	return valueDiff;
	}
	return 0;
	}


	void
	ValueInternalMap::makeBeginIterator( IteratorState &it ) const
	{
	it.map_ = const_cast<ValueInternalMap *>( this );
	it.bucketIndex_ = 0;
	it.itemIndex_ = 0;
	it.link_ = buckets_;
	}


	void
	ValueInternalMap::makeEndIterator( IteratorState &it ) const
	{
	it.map_ = const_cast<ValueInternalMap *>( this );
	it.bucketIndex_ = bucketsSize_;
	it.itemIndex_ = 0;
	it.link_ = 0;
	}


	bool
	ValueInternalMap::equals( const IteratorState &x, const IteratorState &other )
	{
	return x.map_ == other.map_
	&& x.bucketIndex_ == other.bucketIndex_
	&& x.link_ == other.link_
	&& x.itemIndex_ == other.itemIndex_;
	}


	void
	ValueInternalMap::incrementBucket( IteratorState &iterator )
	{
	++iterator.bucketIndex_;
	JSON_ASSERT_MESSAGE( iterator.bucketIndex_ <= iterator.map_->bucketsSize_,
	"ValueInternalMap::increment(): attempting to iterate beyond end." );
	if ( iterator.bucketIndex_ == iterator.map_->bucketsSize_ )
	iterator.link_ = 0;
	else
	iterator.link_ = &(iterator.map_->buckets_[iterator.bucketIndex_]);
	iterator.itemIndex_ = 0;
	}


	void
	ValueInternalMap::increment( IteratorState &iterator )
	{
	JSON_ASSERT_MESSAGE( iterator.map_, "Attempting to iterator using invalid iterator." );
	++iterator.itemIndex_;
	if ( iterator.itemIndex_ == ValueInternalLink::itemPerLink )
	{
	JSON_ASSERT_MESSAGE( iterator.link_ != 0,
	"ValueInternalMap::increment(): attempting to iterate beyond end." );
	iterator.link_ = iterator.link_->next_;
	if ( iterator.link_ == 0 )
	incrementBucket( iterator );
	}
	else if ( iterator.link_->items_[iterator.itemIndex_].isItemAvailable() )
	{
	incrementBucket( iterator );
	}
	}


	void
	ValueInternalMap::decrement( IteratorState &iterator )
	{
	if ( iterator.itemIndex_ == 0 )
	{
	JSON_ASSERT_MESSAGE( iterator.map_, "Attempting to iterate using invalid iterator." );
	if ( iterator.link_ == &iterator.map_->buckets_[iterator.bucketIndex_] )
	{
	JSON_ASSERT_MESSAGE( iterator.bucketIndex_ > 0, "Attempting to iterate beyond beginning." );
	--(iterator.bucketIndex_);
	}
	iterator.link_ = iterator.link_->previous_;
	iterator.itemIndex_ = ValueInternalLink::itemPerLink - 1;
	}
	}


	const char *
	ValueInternalMap::key( const IteratorState &iterator )
	{
	JSON_ASSERT_MESSAGE( iterator.link_, "Attempting to iterate using invalid iterator." );
	return iterator.link_->keys_[iterator.itemIndex_];
	}

	const char *
	ValueInternalMap::key( const IteratorState &iterator, bool &isStatic )
	{
	JSON_ASSERT_MESSAGE( iterator.link_, "Attempting to iterate using invalid iterator." );
	isStatic = iterator.link_->items_[iterator.itemIndex_].isMemberNameStatic();
	return iterator.link_->keys_[iterator.itemIndex_];
	}


	Value &
	ValueInternalMap::value( const IteratorState &iterator )
	{
	JSON_ASSERT_MESSAGE( iterator.link_, "Attempting to iterate using invalid iterator." );
	return iterator.link_->items_[iterator.itemIndex_];
	}


	int
	ValueInternalMap::distance( const IteratorState &x, const IteratorState &y )
	{
	int offset = 0;
	IteratorState it = x;
	while ( !equals( it, y ) )
	increment( it );
	return offset;
	}

	} // namespace Json