rippled/modules/ripple_json/json/json_value.cpp

//------------------------------------------------------------------------------
/*
    Copyright (c) 2011-2013, OpenCoin, Inc.
*/
//==============================================================================

namespace Json
{

const Value Value::null;
const Int Value::minInt = Int ( ~ (UInt (-1) / 2) );
const Int Value::maxInt = Int ( UInt (-1) / 2 );
const UInt Value::maxUInt = UInt (-1);

// A "safe" implementation of strdup. Allow null pointer to be passed.
// Also avoid warning on msvc80.
//
//inline char *safeStringDup( const char *czstring )
//{
//   if ( czstring )
//   {
//      const size_t length = (unsigned int)( strlen(czstring) + 1 );
//      char *newString = static_cast<char *>( malloc( length ) );
//      memcpy( newString, czstring, length );
//      return newString;
//   }
//   return 0;
//}
//
//inline char *safeStringDup( const std::string &str )
//{
//   if ( !str.empty() )
//   {
//      const size_t length = str.length();
//      char *newString = static_cast<char *>( malloc( length + 1 ) );
//      memcpy( newString, str.c_str(), length );
//      newString[length] = 0;
//      return newString;
//   }
//   return 0;
//}

ValueAllocator::~ValueAllocator ()
{
}

class DefaultValueAllocator : public ValueAllocator
{
public:
    virtual ~DefaultValueAllocator ()
    {
    }

    virtual char* makeMemberName ( const char* memberName )
    {
        return duplicateStringValue ( memberName );
    }

    virtual void releaseMemberName ( char* memberName )
    {
        releaseStringValue ( memberName );
    }

    virtual char* duplicateStringValue ( const char* value,
                                         unsigned int length = unknown )
    {
        //@todo invesgate this old optimization
        //if ( !value  ||  value[0] == 0 )
        //   return 0;

        if ( length == unknown )
            length = (unsigned int)strlen (value);

        char* newString = static_cast<char*> ( malloc ( length + 1 ) );
        memcpy ( newString, value, length );
        newString[length] = 0;
        return newString;
    }

    virtual void releaseStringValue ( char* value )
    {
        if ( value )
            free ( value );
    }
};

static ValueAllocator*& valueAllocator ()
{
    static ValueAllocator* valueAllocator = new DefaultValueAllocator;
    return valueAllocator;
}

static struct DummyValueAllocatorInitializer
{
    DummyValueAllocatorInitializer ()
    {
        valueAllocator ();     // ensure valueAllocator() statics are initialized before main().
    }
} dummyValueAllocatorInitializer;



// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// ValueInternals...
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
#ifdef JSON_VALUE_USE_INTERNAL_MAP
# include "json_internalarray.inl"
# include "json_internalmap.inl"
#endif // JSON_VALUE_USE_INTERNAL_MAP

# include "json_valueiterator.inl"


// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// class Value::CommentInfo
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////


Value::CommentInfo::CommentInfo ()
    : comment_ ( 0 )
{
}

Value::CommentInfo::~CommentInfo ()
{
    if ( comment_ )
        valueAllocator ()->releaseStringValue ( comment_ );
}


void
Value::CommentInfo::setComment ( const char* text )
{
    if ( comment_ )
        valueAllocator ()->releaseStringValue ( comment_ );

    JSON_ASSERT ( text );
    JSON_ASSERT_MESSAGE ( text[0] == '\0' || text[0] == '/', "Comments must start with /");
    // It seems that /**/ style comments are acceptable as well.
    comment_ = valueAllocator ()->duplicateStringValue ( text );
}


// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// class Value::CZString
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
# ifndef JSON_VALUE_USE_INTERNAL_MAP

// Notes: index_ indicates if the string was allocated when
// a string is stored.

Value::CZString::CZString ( int index )
    : cstr_ ( 0 )
    , index_ ( index )
{
}

Value::CZString::CZString ( const char* cstr, DuplicationPolicy allocate )
    : cstr_ ( allocate == duplicate ? valueAllocator ()->makeMemberName (cstr)
              : cstr )
    , index_ ( allocate )
{
}

Value::CZString::CZString ( const CZString& other )
    : cstr_ ( other.index_ != noDuplication&&   other.cstr_ != 0
              ?  valueAllocator ()->makeMemberName ( other.cstr_ )
              : other.cstr_ )
    , index_ ( other.cstr_ ? (other.index_ == noDuplication ? noDuplication : duplicate)
               : other.index_ )
{
}

Value::CZString::~CZString ()
{
    if ( cstr_  &&  index_ == duplicate )
        valueAllocator ()->releaseMemberName ( const_cast<char*> ( cstr_ ) );
}

void
Value::CZString::swap ( CZString& other )
{
    std::swap ( cstr_, other.cstr_ );
    std::swap ( index_, other.index_ );
}

Value::CZString&
Value::CZString::operator = ( const CZString& other )
{
    CZString temp ( other );
    swap ( temp );
    return *this;
}

bool
Value::CZString::operator< ( const CZString& other ) const
{
    if ( cstr_ )
        return strcmp ( cstr_, other.cstr_ ) < 0;

    return index_ < other.index_;
}

bool
Value::CZString::operator== ( const CZString& other ) const
{
    if ( cstr_ )
        return strcmp ( cstr_, other.cstr_ ) == 0;

    return index_ == other.index_;
}


int
Value::CZString::index () const
{
    return index_;
}


const char*
Value::CZString::c_str () const
{
    return cstr_;
}

bool
Value::CZString::isStaticString () const
{
    return index_ == noDuplication;
}

#endif // ifndef JSON_VALUE_USE_INTERNAL_MAP


// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// class Value::Value
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////
// //////////////////////////////////////////////////////////////////

/*! \internal Default constructor initialization must be equivalent to:
 * memset( this, 0, sizeof(Value) )
 * This optimization is used in ValueInternalMap fast allocator.
 */
Value::Value ( ValueType type )
    : type_ ( type )
    , allocated_ ( 0 )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    switch ( type )
    {
    case nullValue:
        break;

    case intValue:
    case uintValue:
        value_.int_ = 0;
        break;

    case realValue:
        value_.real_ = 0.0;
        break;

    case stringValue:
        value_.string_ = 0;
        break;
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
    case objectValue:
        value_.map_ = new ObjectValues ();
        break;
#else

    case arrayValue:
        value_.array_ = arrayAllocator ()->newArray ();
        break;

    case objectValue:
        value_.map_ = mapAllocator ()->newMap ();
        break;
#endif

    case booleanValue:
        value_.bool_ = false;
        break;

    default:
        JSON_ASSERT_UNREACHABLE;
    }
}


Value::Value ( Int value )
    : type_ ( intValue )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.int_ = value;
}


Value::Value ( UInt value )
    : type_ ( uintValue )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.uint_ = value;
}

Value::Value ( double value )
    : type_ ( realValue )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.real_ = value;
}

Value::Value ( const char* value )
    : type_ ( stringValue )
    , allocated_ ( true )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.string_ = valueAllocator ()->duplicateStringValue ( value );
}


Value::Value ( const char* beginValue,
               const char* endValue )
    : type_ ( stringValue )
    , allocated_ ( true )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.string_ = valueAllocator ()->duplicateStringValue ( beginValue,
                     UInt (endValue - beginValue) );
}


Value::Value ( const std::string& value )
    : type_ ( stringValue )
    , allocated_ ( true )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.string_ = valueAllocator ()->duplicateStringValue ( value.c_str (),
                     (unsigned int)value.length () );

}
Value::Value (beast::String const& beastString)
    : type_ ( stringValue )
    , allocated_ ( true )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.string_ = valueAllocator ()->duplicateStringValue ( beastString.toStdString ().c_str (),
                     (unsigned int)beastString.length () );

}

Value::Value ( const StaticString& value )
    : type_ ( stringValue )
    , allocated_ ( false )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.string_ = const_cast<char*> ( value.c_str () );
}


# ifdef JSON_USE_CPPTL
Value::Value ( const CppTL::ConstString& value )
    : type_ ( stringValue )
    , allocated_ ( true )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.string_ = valueAllocator ()->duplicateStringValue ( value, value.length () );
}
# endif

Value::Value ( bool value )
    : type_ ( booleanValue )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    value_.bool_ = value;
}


Value::Value ( const Value& other )
    : type_ ( other.type_ )
    , comments_ ( 0 )
# ifdef JSON_VALUE_USE_INTERNAL_MAP
    , itemIsUsed_ ( 0 )
#endif
{
    switch ( type_ )
    {
    case nullValue:
    case intValue:
    case uintValue:
    case realValue:
    case booleanValue:
        value_ = other.value_;
        break;

    case stringValue:
        if ( other.value_.string_ )
        {
            value_.string_ = valueAllocator ()->duplicateStringValue ( other.value_.string_ );
            allocated_ = true;
        }
        else
            value_.string_ = 0;

        break;
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
    case objectValue:
        value_.map_ = new ObjectValues ( *other.value_.map_ );
        break;
#else

    case arrayValue:
        value_.array_ = arrayAllocator ()->newArrayCopy ( *other.value_.array_ );
        break;

    case objectValue:
        value_.map_ = mapAllocator ()->newMapCopy ( *other.value_.map_ );
        break;
#endif

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    if ( other.comments_ )
    {
        comments_ = new CommentInfo[numberOfCommentPlacement];

        for ( int comment = 0; comment < numberOfCommentPlacement; ++comment )
        {
            const CommentInfo& otherComment = other.comments_[comment];

            if ( otherComment.comment_ )
                comments_[comment].setComment ( otherComment.comment_ );
        }
    }
}


Value::~Value ()
{
    switch ( type_ )
    {
    case nullValue:
    case intValue:
    case uintValue:
    case realValue:
    case booleanValue:
        break;

    case stringValue:
        if ( allocated_ )
            valueAllocator ()->releaseStringValue ( value_.string_ );

        break;
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
    case objectValue:
        delete value_.map_;
        break;
#else

    case arrayValue:
        arrayAllocator ()->destructArray ( value_.array_ );
        break;

    case objectValue:
        mapAllocator ()->destructMap ( value_.map_ );
        break;
#endif

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    if ( comments_ )
        delete[] comments_;
}

Value&
Value::operator= ( const Value& other )
{
    Value temp ( other );
    swap ( temp );
    return *this;
}

void
Value::swap ( Value& other )
{
    ValueType temp = type_;
    type_ = other.type_;
    other.type_ = temp;
    std::swap ( value_, other.value_ );
    int temp2 = allocated_;
    allocated_ = other.allocated_;
    other.allocated_ = temp2;
}

ValueType
Value::type () const
{
    return type_;
}


int
Value::compare ( const Value& other )
{
    /*
    int typeDelta = other.type_ - type_;
    switch ( type_ )
    {
    case nullValue:

       return other.type_ == type_;
    case intValue:
       if ( other.type_.isNumeric()
    case uintValue:
    case realValue:
    case booleanValue:
       break;
    case stringValue,
       break;
    case arrayValue:
       delete value_.array_;
       break;
    case objectValue:
       delete value_.map_;
    default:
       JSON_ASSERT_UNREACHABLE;
    }
    */
    return 0;  // unreachable
}

bool
Value::operator < ( const Value& other ) const
{
    int typeDelta = type_ - other.type_;

    if ( typeDelta )
        return typeDelta < 0 ? true : false;

    switch ( type_ )
    {
    case nullValue:
        return false;

    case intValue:
        return value_.int_ < other.value_.int_;

    case uintValue:
        return value_.uint_ < other.value_.uint_;

    case realValue:
        return value_.real_ < other.value_.real_;

    case booleanValue:
        return value_.bool_ < other.value_.bool_;

    case stringValue:
        return ( value_.string_ == 0  &&  other.value_.string_ )
               || ( other.value_.string_
                    &&  value_.string_
                    && strcmp ( value_.string_, other.value_.string_ ) < 0 );
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
    case objectValue:
    {
        int delta = int ( value_.map_->size () - other.value_.map_->size () );

        if ( delta )
            return delta < 0;

        return (*value_.map_) < (*other.value_.map_);
    }

#else

    case arrayValue:
        return value_.array_->compare ( * (other.value_.array_) ) < 0;

    case objectValue:
        return value_.map_->compare ( * (other.value_.map_) ) < 0;
#endif

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return 0;  // unreachable
}

bool
Value::operator <= ( const Value& other ) const
{
    return ! (other > *this);
}

bool
Value::operator >= ( const Value& other ) const
{
    return ! (*this < other);
}

bool
Value::operator > ( const Value& other ) const
{
    return other < *this;
}

bool
Value::operator == ( const Value& other ) const
{
    //if ( type_ != other.type_ )
    // GCC 2.95.3 says:
    // attempt to take address of bit-field structure member `Json::Value::type_'
    // Beats me, but a temp solves the problem.
    int temp = other.type_;

    if ( type_ != temp )
        return false;

    switch ( type_ )
    {
    case nullValue:
        return true;

    case intValue:
        return value_.int_ == other.value_.int_;

    case uintValue:
        return value_.uint_ == other.value_.uint_;

    case realValue:
        return value_.real_ == other.value_.real_;

    case booleanValue:
        return value_.bool_ == other.value_.bool_;

    case stringValue:
        return ( value_.string_ == other.value_.string_ )
               || ( other.value_.string_
                    &&  value_.string_
                    && strcmp ( value_.string_, other.value_.string_ ) == 0 );
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
    case objectValue:
        return value_.map_->size () == other.value_.map_->size ()
               && (*value_.map_) == (*other.value_.map_);
#else

    case arrayValue:
        return value_.array_->compare ( * (other.value_.array_) ) == 0;

    case objectValue:
        return value_.map_->compare ( * (other.value_.map_) ) == 0;
#endif

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return 0;  // unreachable
}

bool
Value::operator != ( const Value& other ) const
{
    return ! ( *this == other );
}

const char*
Value::asCString () const
{
    JSON_ASSERT ( type_ == stringValue );
    return value_.string_;
}


std::string
Value::asString () const
{
    switch ( type_ )
    {
    case nullValue:
        return "";

    case stringValue:
        return value_.string_ ? value_.string_ : "";

    case booleanValue:
        return value_.bool_ ? "true" : "false";

    case intValue:
        return lexicalCastThrow <std::string> (value_.int_);

    case uintValue:
    case realValue:
    case arrayValue:
    case objectValue:
        JSON_ASSERT_MESSAGE ( false, "Type is not convertible to string" );

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return ""; // unreachable
}

# ifdef JSON_USE_CPPTL
CppTL::ConstString
Value::asConstString () const
{
    return CppTL::ConstString ( asString ().c_str () );
}
# endif

Value::Int
Value::asInt () const
{
    switch ( type_ )
    {
    case nullValue:
        return 0;

    case intValue:
        return value_.int_;

    case uintValue:
        JSON_ASSERT_MESSAGE ( value_.uint_ < (unsigned)maxInt, "integer out of signed integer range" );
        return value_.uint_;

    case realValue:
        JSON_ASSERT_MESSAGE ( value_.real_ >= minInt  &&  value_.real_ <= maxInt, "Real out of signed integer range" );
        return Int ( value_.real_ );

    case booleanValue:
        return value_.bool_ ? 1 : 0;

    case stringValue:
        return lexicalCastThrow <int> (value_.string_);

    case arrayValue:
    case objectValue:
        JSON_ASSERT_MESSAGE ( false, "Type is not convertible to int" );

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return 0; // unreachable;
}

Value::UInt
Value::asUInt () const
{
    switch ( type_ )
    {
    case nullValue:
        return 0;

    case intValue:
        JSON_ASSERT_MESSAGE ( value_.int_ >= 0, "Negative integer can not be converted to unsigned integer" );
        return value_.int_;

    case uintValue:
        return value_.uint_;

    case realValue:
        JSON_ASSERT_MESSAGE ( value_.real_ >= 0  &&  value_.real_ <= maxUInt,  "Real out of unsigned integer range" );
        return UInt ( value_.real_ );

    case booleanValue:
        return value_.bool_ ? 1 : 0;

    case stringValue:
        return lexicalCastThrow <unsigned int> (value_.string_);

    case arrayValue:
    case objectValue:
        JSON_ASSERT_MESSAGE ( false, "Type is not convertible to uint" );

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return 0; // unreachable;
}

double
Value::asDouble () const
{
    switch ( type_ )
    {
    case nullValue:
        return 0.0;

    case intValue:
        return value_.int_;

    case uintValue:
        return value_.uint_;

    case realValue:
        return value_.real_;

    case booleanValue:
        return value_.bool_ ? 1.0 : 0.0;

    case stringValue:
    case arrayValue:
    case objectValue:
        JSON_ASSERT_MESSAGE ( false, "Type is not convertible to double" );

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return 0; // unreachable;
}

bool
Value::asBool () const
{
    switch ( type_ )
    {
    case nullValue:
        return false;

    case intValue:
    case uintValue:
        return value_.int_ != 0;

    case realValue:
        return value_.real_ != 0.0;

    case booleanValue:
        return value_.bool_;

    case stringValue:
        return value_.string_  &&  value_.string_[0] != 0;

    case arrayValue:
    case objectValue:
        return value_.map_->size () != 0;

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return false; // unreachable;
}


bool
Value::isConvertibleTo ( ValueType other ) const
{
    switch ( type_ )
    {
    case nullValue:
        return true;

    case intValue:
        return ( other == nullValue  &&  value_.int_ == 0 )
               || other == intValue
               || ( other == uintValue  && value_.int_ >= 0 )
               || other == realValue
               || other == stringValue
               || other == booleanValue;

    case uintValue:
        return ( other == nullValue  &&  value_.uint_ == 0 )
               || ( other == intValue  && value_.uint_ <= (unsigned)maxInt )
               || other == uintValue
               || other == realValue
               || other == stringValue
               || other == booleanValue;

    case realValue:
        return ( other == nullValue  &&  value_.real_ == 0.0 )
               || ( other == intValue  &&  value_.real_ >= minInt  &&  value_.real_ <= maxInt )
               || ( other == uintValue  &&  value_.real_ >= 0  &&  value_.real_ <= maxUInt )
               || other == realValue
               || other == stringValue
               || other == booleanValue;

    case booleanValue:
        return ( other == nullValue  &&  value_.bool_ == false )
               || other == intValue
               || other == uintValue
               || other == realValue
               || other == stringValue
               || other == booleanValue;

    case stringValue:
        return other == stringValue
               || ( other == nullValue  &&  (!value_.string_  ||  value_.string_[0] == 0) );

    case arrayValue:
        return other == arrayValue
               ||  ( other == nullValue  &&  value_.map_->size () == 0 );

    case objectValue:
        return other == objectValue
               ||  ( other == nullValue  &&  value_.map_->size () == 0 );

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return false; // unreachable;
}


/// Number of values in array or object
Value::UInt
Value::size () const
{
    switch ( type_ )
    {
    case nullValue:
    case intValue:
    case uintValue:
    case realValue:
    case booleanValue:
    case stringValue:
        return 0;
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:  // size of the array is highest index + 1
        if ( !value_.map_->empty () )
        {
            ObjectValues::const_iterator itLast = value_.map_->end ();
            --itLast;
            return (*itLast).first.index () + 1;
        }

        return 0;

    case objectValue:
        return Int ( value_.map_->size () );
#else

    case arrayValue:
        return Int ( value_.array_->size () );

    case objectValue:
        return Int ( value_.map_->size () );
#endif

    default:
        JSON_ASSERT_UNREACHABLE;
    }

    return 0; // unreachable;
}


bool
Value::empty () const
{
    if ( isNull () || isArray () || isObject () )
        return size () == 0u;
    else
        return false;
}


bool
Value::operator! () const
{
    return isNull ();
}


void
Value::clear ()
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == arrayValue  || type_ == objectValue );

    switch ( type_ )
    {
#ifndef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
    case objectValue:
        value_.map_->clear ();
        break;
#else

    case arrayValue:
        value_.array_->clear ();
        break;

    case objectValue:
        value_.map_->clear ();
        break;
#endif

    default:
        break;
    }
}

void
Value::resize ( UInt newSize )
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == arrayValue );

    if ( type_ == nullValue )
        *this = Value ( arrayValue );

#ifndef JSON_VALUE_USE_INTERNAL_MAP
    UInt oldSize = size ();

    if ( newSize == 0 )
        clear ();
    else if ( newSize > oldSize )
        (*this)[ newSize - 1 ];
    else
    {
        for ( UInt index = newSize; index < oldSize; ++index )
            value_.map_->erase ( index );

        assert ( size () == newSize );
    }

#else
    value_.array_->resize ( newSize );
#endif
}


Value&
Value::operator[] ( UInt index )
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == arrayValue );

    if ( type_ == nullValue )
        *this = Value ( arrayValue );

#ifndef JSON_VALUE_USE_INTERNAL_MAP
    CZString key ( index );
    ObjectValues::iterator it = value_.map_->lower_bound ( key );

    if ( it != value_.map_->end ()  &&  (*it).first == key )
        return (*it).second;

    ObjectValues::value_type defaultValue ( key, null );
    it = value_.map_->insert ( it, defaultValue );
    return (*it).second;
#else
    return value_.array_->resolveReference ( index );
#endif
}


const Value&
Value::operator[] ( UInt index ) const
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == arrayValue );

    if ( type_ == nullValue )
        return null;

#ifndef JSON_VALUE_USE_INTERNAL_MAP
    CZString key ( index );
    ObjectValues::const_iterator it = value_.map_->find ( key );

    if ( it == value_.map_->end () )
        return null;

    return (*it).second;
#else
    Value* value = value_.array_->find ( index );
    return value ? *value : null;
#endif
}


Value&
Value::operator[] ( const char* key )
{
    return resolveReference ( key, false );
}


Value&
Value::resolveReference ( const char* key,
                          bool isStatic )
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == objectValue );

    if ( type_ == nullValue )
        *this = Value ( objectValue );

#ifndef JSON_VALUE_USE_INTERNAL_MAP
    CZString actualKey ( key, isStatic ? CZString::noDuplication
                         : CZString::duplicateOnCopy );
    ObjectValues::iterator it = value_.map_->lower_bound ( actualKey );

    if ( it != value_.map_->end ()  &&  (*it).first == actualKey )
        return (*it).second;

    ObjectValues::value_type defaultValue ( actualKey, null );
    it = value_.map_->insert ( it, defaultValue );
    Value& value = (*it).second;
    return value;
#else
    return value_.map_->resolveReference ( key, isStatic );
#endif
}


Value
Value::get ( UInt index,
             const Value& defaultValue ) const
{
    const Value* value = & ((*this)[index]);
    return value == &null ? defaultValue : *value;
}


bool
Value::isValidIndex ( UInt index ) const
{
    return index < size ();
}



const Value&
Value::operator[] ( const char* key ) const
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == objectValue );

    if ( type_ == nullValue )
        return null;

#ifndef JSON_VALUE_USE_INTERNAL_MAP
    CZString actualKey ( key, CZString::noDuplication );
    ObjectValues::const_iterator it = value_.map_->find ( actualKey );

    if ( it == value_.map_->end () )
        return null;

    return (*it).second;
#else
    const Value* value = value_.map_->find ( key );
    return value ? *value : null;
#endif
}


Value&
Value::operator[] ( const std::string& key )
{
    return (*this)[ key.c_str () ];
}


const Value&
Value::operator[] ( const std::string& key ) const
{
    return (*this)[ key.c_str () ];
}

Value&
Value::operator[] ( const StaticString& key )
{
    return resolveReference ( key, true );
}


# ifdef JSON_USE_CPPTL
Value&
Value::operator[] ( const CppTL::ConstString& key )
{
    return (*this)[ key.c_str () ];
}


const Value&
Value::operator[] ( const CppTL::ConstString& key ) const
{
    return (*this)[ key.c_str () ];
}
# endif


Value&
Value::append ( const Value& value )
{
    return (*this)[size ()] = value;
}


Value
Value::get ( const char* key,
             const Value& defaultValue ) const
{
    const Value* value = & ((*this)[key]);
    return value == &null ? defaultValue : *value;
}


Value
Value::get ( const std::string& key,
             const Value& defaultValue ) const
{
    return get ( key.c_str (), defaultValue );
}

Value
Value::removeMember ( const char* key )
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == objectValue );

    if ( type_ == nullValue )
        return null;

#ifndef JSON_VALUE_USE_INTERNAL_MAP
    CZString actualKey ( key, CZString::noDuplication );
    ObjectValues::iterator it = value_.map_->find ( actualKey );

    if ( it == value_.map_->end () )
        return null;

    Value old (it->second);
    value_.map_->erase (it);
    return old;
#else
    Value* value = value_.map_->find ( key );

    if (value)
    {
        Value old (*value);
        value_.map_.remove ( key );
        return old;
    }
    else
    {
        return null;
    }

#endif
}

Value
Value::removeMember ( const std::string& key )
{
    return removeMember ( key.c_str () );
}

# ifdef JSON_USE_CPPTL
Value
Value::get ( const CppTL::ConstString& key,
             const Value& defaultValue ) const
{
    return get ( key.c_str (), defaultValue );
}
# endif

bool
Value::isMember ( const char* key ) const
{
    const Value* value = & ((*this)[key]);
    return value != &null;
}


bool
Value::isMember ( const std::string& key ) const
{
    return isMember ( key.c_str () );
}


# ifdef JSON_USE_CPPTL
bool
Value::isMember ( const CppTL::ConstString& key ) const
{
    return isMember ( key.c_str () );
}
#endif

Value::Members
Value::getMemberNames () const
{
    JSON_ASSERT ( type_ == nullValue  ||  type_ == objectValue );

    if ( type_ == nullValue )
        return Value::Members ();

    Members members;
    members.reserve ( value_.map_->size () );
#ifndef JSON_VALUE_USE_INTERNAL_MAP
    ObjectValues::const_iterator it = value_.map_->begin ();
    ObjectValues::const_iterator itEnd = value_.map_->end ();

    for ( ; it != itEnd; ++it )
        members.push_back ( std::string ( (*it).first.c_str () ) );

#else
    ValueInternalMap::IteratorState it;
    ValueInternalMap::IteratorState itEnd;
    value_.map_->makeBeginIterator ( it );
    value_.map_->makeEndIterator ( itEnd );

    for ( ; !ValueInternalMap::equals ( it, itEnd ); ValueInternalMap::increment (it) )
        members.push_back ( std::string ( ValueInternalMap::key ( it ) ) );

#endif
    return members;
}
//
//# ifdef JSON_USE_CPPTL
//EnumMemberNames
//Value::enumMemberNames() const
//{
//   if ( type_ == objectValue )
//   {
//      return CppTL::Enum::any(  CppTL::Enum::transform(
//         CppTL::Enum::keys( *(value_.map_), CppTL::Type<const CZString &>() ),
//         MemberNamesTransform() ) );
//   }
//   return EnumMemberNames();
//}
//
//
//EnumValues
//Value::enumValues() const
//{
//   if ( type_ == objectValue  ||  type_ == arrayValue )
//      return CppTL::Enum::anyValues( *(value_.map_),
//                                     CppTL::Type<const Value &>() );
//   return EnumValues();
//}
//
//# endif


bool
Value::isNull () const
{
    return type_ == nullValue;
}


bool
Value::isBool () const
{
    return type_ == booleanValue;
}


bool
Value::isInt () const
{
    return type_ == intValue;
}


bool
Value::isUInt () const
{
    return type_ == uintValue;
}


bool
Value::isIntegral () const
{
    return type_ == intValue
           ||  type_ == uintValue
           ||  type_ == booleanValue;
}


bool
Value::isDouble () const
{
    return type_ == realValue;
}


bool
Value::isNumeric () const
{
    return isIntegral () || isDouble ();
}


bool
Value::isString () const
{
    return type_ == stringValue;
}


bool
Value::isArray () const
{
    return type_ == nullValue  ||  type_ == arrayValue;
}


bool
Value::isObject () const
{
    return type_ == nullValue  ||  type_ == objectValue;
}


void
Value::setComment ( const char* comment,
                    CommentPlacement placement )
{
    if ( !comments_ )
        comments_ = new CommentInfo[numberOfCommentPlacement];

    comments_[placement].setComment ( comment );
}


void
Value::setComment ( const std::string& comment,
                    CommentPlacement placement )
{
    setComment ( comment.c_str (), placement );
}


bool
Value::hasComment ( CommentPlacement placement ) const
{
    return comments_ != 0  &&  comments_[placement].comment_ != 0;
}

std::string
Value::getComment ( CommentPlacement placement ) const
{
    if ( hasComment (placement) )
        return comments_[placement].comment_;

    return "";
}


std::string
Value::toStyledString () const
{
    StyledWriter writer;
    return writer.write ( *this );
}


Value::const_iterator
Value::begin () const
{
    switch ( type_ )
    {
#ifdef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
        if ( value_.array_ )
        {
            ValueInternalArray::IteratorState it;
            value_.array_->makeBeginIterator ( it );
            return const_iterator ( it );
        }

        break;

    case objectValue:
        if ( value_.map_ )
        {
            ValueInternalMap::IteratorState it;
            value_.map_->makeBeginIterator ( it );
            return const_iterator ( it );
        }

        break;
#else

    case arrayValue:
    case objectValue:
        if ( value_.map_ )
            return const_iterator ( value_.map_->begin () );

        break;
#endif

    default:
        break;
    }

    return const_iterator ();
}

Value::const_iterator
Value::end () const
{
    switch ( type_ )
    {
#ifdef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
        if ( value_.array_ )
        {
            ValueInternalArray::IteratorState it;
            value_.array_->makeEndIterator ( it );
            return const_iterator ( it );
        }

        break;

    case objectValue:
        if ( value_.map_ )
        {
            ValueInternalMap::IteratorState it;
            value_.map_->makeEndIterator ( it );
            return const_iterator ( it );
        }

        break;
#else

    case arrayValue:
    case objectValue:
        if ( value_.map_ )
            return const_iterator ( value_.map_->end () );

        break;
#endif

    default:
        break;
    }

    return const_iterator ();
}


Value::iterator
Value::begin ()
{
    switch ( type_ )
    {
#ifdef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
        if ( value_.array_ )
        {
            ValueInternalArray::IteratorState it;
            value_.array_->makeBeginIterator ( it );
            return iterator ( it );
        }

        break;

    case objectValue:
        if ( value_.map_ )
        {
            ValueInternalMap::IteratorState it;
            value_.map_->makeBeginIterator ( it );
            return iterator ( it );
        }

        break;
#else

    case arrayValue:
    case objectValue:
        if ( value_.map_ )
            return iterator ( value_.map_->begin () );

        break;
#endif

    default:
        break;
    }

    return iterator ();
}

Value::iterator
Value::end ()
{
    switch ( type_ )
    {
#ifdef JSON_VALUE_USE_INTERNAL_MAP

    case arrayValue:
        if ( value_.array_ )
        {
            ValueInternalArray::IteratorState it;
            value_.array_->makeEndIterator ( it );
            return iterator ( it );
        }

        break;

    case objectValue:
        if ( value_.map_ )
        {
            ValueInternalMap::IteratorState it;
            value_.map_->makeEndIterator ( it );
            return iterator ( it );
        }

        break;
#else

    case arrayValue:
    case objectValue:
        if ( value_.map_ )
            return iterator ( value_.map_->end () );

        break;
#endif

    default:
        break;
    }

    return iterator ();
}


// class PathArgument
// //////////////////////////////////////////////////////////////////

PathArgument::PathArgument ()
    : kind_ ( kindNone )
{
}


PathArgument::PathArgument ( Value::UInt index )
    : index_ ( index )
    , kind_ ( kindIndex )
{
}


PathArgument::PathArgument ( const char* key )
    : key_ ( key )
    , kind_ ( kindKey )
{
}


PathArgument::PathArgument ( const std::string& key )
    : key_ ( key.c_str () )
    , kind_ ( kindKey )
{
}

// class Path
// //////////////////////////////////////////////////////////////////

Path::Path ( const std::string& path,
             const PathArgument& a1,
             const PathArgument& a2,
             const PathArgument& a3,
             const PathArgument& a4,
             const PathArgument& a5 )
{
    InArgs in;
    in.push_back ( &a1 );
    in.push_back ( &a2 );
    in.push_back ( &a3 );
    in.push_back ( &a4 );
    in.push_back ( &a5 );
    makePath ( path, in );
}


void
Path::makePath ( const std::string& path,
                 const InArgs& in )
{
    const char* current = path.c_str ();
    const char* end = current + path.length ();
    InArgs::const_iterator itInArg = in.begin ();

    while ( current != end )
    {
        if ( *current == '[' )
        {
            ++current;

            if ( *current == '%' )
                addPathInArg ( path, in, itInArg, PathArgument::kindIndex );
            else
            {
                Value::UInt index = 0;

                for ( ; current != end && *current >= '0'  &&  *current <= '9'; ++current )
                    index = index * 10 + Value::UInt (*current - '0');

                args_.push_back ( index );
            }

            if ( current == end  ||  *current++ != ']' )
                invalidPath ( path, int (current - path.c_str ()) );
        }
        else if ( *current == '%' )
        {
            addPathInArg ( path, in, itInArg, PathArgument::kindKey );
            ++current;
        }
        else if ( *current == '.' )
        {
            ++current;
        }
        else
        {
            const char* beginName = current;

            while ( current != end  &&  !strchr ( "[.", *current ) )
                ++current;

            args_.push_back ( std::string ( beginName, current ) );
        }
    }
}


void
Path::addPathInArg ( const std::string& path,
                     const InArgs& in,
                     InArgs::const_iterator& itInArg,
                     PathArgument::Kind kind )
{
    if ( itInArg == in.end () )
    {
        // Error: missing argument %d
    }
    else if ( (*itInArg)->kind_ != kind )
    {
        // Error: bad argument type
    }
    else
    {
        args_.push_back ( **itInArg );
    }
}


void
Path::invalidPath ( const std::string& path,
                    int location )
{
    // Error: invalid path.
}


const Value&
Path::resolve ( const Value& root ) const
{
    const Value* node = &root;

    for ( Args::const_iterator it = args_.begin (); it != args_.end (); ++it )
    {
        const PathArgument& arg = *it;

        if ( arg.kind_ == PathArgument::kindIndex )
        {
            if ( !node->isArray ()  ||  node->isValidIndex ( arg.index_ ) )
            {
                // Error: unable to resolve path (array value expected at position...
            }

            node = & ((*node)[arg.index_]);
        }
        else if ( arg.kind_ == PathArgument::kindKey )
        {
            if ( !node->isObject () )
            {
                // Error: unable to resolve path (object value expected at position...)
            }

            node = & ((*node)[arg.key_]);

            if ( node == &Value::null )
            {
                // Error: unable to resolve path (object has no member named '' at position...)
            }
        }
    }

    return *node;
}


Value
Path::resolve ( const Value& root,
                const Value& defaultValue ) const
{
    const Value* node = &root;

    for ( Args::const_iterator it = args_.begin (); it != args_.end (); ++it )
    {
        const PathArgument& arg = *it;

        if ( arg.kind_ == PathArgument::kindIndex )
        {
            if ( !node->isArray ()  ||  node->isValidIndex ( arg.index_ ) )
                return defaultValue;

            node = & ((*node)[arg.index_]);
        }
        else if ( arg.kind_ == PathArgument::kindKey )
        {
            if ( !node->isObject () )
                return defaultValue;

            node = & ((*node)[arg.key_]);

            if ( node == &Value::null )
                return defaultValue;
        }
    }

    return *node;
}


Value&
Path::make ( Value& root ) const
{
    Value* node = &root;

    for ( Args::const_iterator it = args_.begin (); it != args_.end (); ++it )
    {
        const PathArgument& arg = *it;

        if ( arg.kind_ == PathArgument::kindIndex )
        {
            if ( !node->isArray () )
            {
                // Error: node is not an array at position ...
            }

            node = & ((*node)[arg.index_]);
        }
        else if ( arg.kind_ == PathArgument::kindKey )
        {
            if ( !node->isObject () )
            {
                // Error: node is not an object at position...
            }

            node = & ((*node)[arg.key_]);
        }
    }

    return *node;
}


} // namespace Json