OpenSceneGraph/include/osgIntrospection/Value

#ifndef OSGINTROSPECTION_VALUE_
#define OSGINTROSPECTION_VALUE_

#include <osgIntrospection/Export>
#include <osgIntrospection/Reflection>

#include <vector>
#include <memory>
#include <string>

namespace osgIntrospection
{

    class Type;

    class OSGINTROSPECTION_EXPORT Value
    {
    public:
        /// Default constructor. Initializes internal structures
        /// so that the Type returned by getType() is typeof(void),
        /// and the value is empty so that isEmpty() returns true.
        /// Be careful when using empty values, as some operations
        /// on them may throw an exception.
        inline Value();

        /// Direct initialization constructor for void pointers.
        /// Although one of the constructor templates below could
        /// certainly handle void pointers as well, we need to treat 
        /// them separately because void* can't be dereferenced.
        inline Value(void *v);

        /// Direct initialization constructor for const void pointers.
        /// Although one of the constructor templates below could
        /// certainly handle void pointers as well, we need to treat 
        /// them separately because void* can't be dereferenced.
        inline Value(const void *v);

        /// Direct initialization constructor template for non-const
        /// pointers. By initializing an instance of Value through
        /// this constructor, internal structures will be configured
        /// to handle polymorphic types. This means you'll be able to
        /// call getInstanceType() to get the actual type of the
        /// dereferenced value.
        template<typename T> Value(T *v);

        /// Direct initialization constructor template for non-const
        /// pointers. By initializing an instance of Value through
        /// this constructor, internal structures will be configured
        /// to handle polymorphic types. This means you'll be able to
        /// call getInstanceType() to get the actual type of the
        /// dereferenced value.
        template<typename T> Value(const T *v);

        /// Direct initialization constructor template for all types
        /// that are not handled by any of the constructors above.
        /// Calling getInstanceType() on an instance constructed
        /// this way returns the same as getType().
        template<typename T> Value(const T &v);

        /// Copy constructor. The underlying value's type must have
        /// consistent copy semantics.
        inline Value(const Value &copy);

        /// Destructor. Frees internal resources but it does NOT delete
        /// the value held. For example, this function will produce a
        /// memory leak:  void f() { Value v(new int); }
        inline ~Value();

        /// Assignment operator. Behaves like the copy constructor.
        inline Value &operator=(const Value &copy);

        /// Returns whether the value is a pointer and it points to
        /// something whose type is different than void.
        inline bool isTypedPointer() const;

        /// Returns whether this Value is empty.
        inline bool isEmpty() const;

        /// Returns whether the value is a null pointer.
        inline bool isNullPointer() const;

        /// Returns the exact type of the value held.
        inline const Type &getType() const;

        /// If the value is a pointer to a non-void type, this method
        /// returns the actual type of the dereferenced pointer. Please
        /// note it is not the same as getType().getPointedType(),
        /// because the latter would return the non-polymorphic type.
        /// If the value is not a pointer, this method behaves like
        /// getType().
        inline const Type &getInstanceType() const;

        /// Equal to operator.
        bool operator==(const Value &other) const;

        /// Less than or equal to operator.
        bool operator<=(const Value &other) const;
        
        /// Inequality test operator. Returns !operator==(other).
        bool operator!=(const Value &other) const;

        /// Greater than operator. Returns !operator<=(other).
        bool operator>(const Value &other) const;

        /// Less than operator. Returns !operator==(other) && operator<=(other).
        bool operator<(const Value &other) const;
        
        /// Greater than or equal to operator. Returns operator==(other) || !operator<=(other)
        bool operator>=(const Value &other) const;

        /// Tries to convert this instance to a Value of the given type.
        /// The conversion is performed by rendering to a temporary stream
        /// in the source format and trying to read back from the stream
        /// in the destination format. If either the source or destination
        /// types, or both, don't have a ReaderWriter object, the conversion
        /// fails and an exception is thrown. If the conversion can't be
        /// completed for other reasons, other exceptions may be thrown.
        Value convertTo(const Type &outtype) const;

        /// Tries to convert this instance to a Value of the given type.
        /// The conversion is performed by rendering to a temporary stream
        /// in the source format and trying to read back from the stream
        /// in the destination format. If either the source or destination
        /// types, or both, don't have a ReaderWriter object, the conversion
        /// fails and an empty Value is returned.
        /// Please note that unlike convertTo(), this method does not 
        /// intentionally throw any exceptions.
        Value tryConvertTo(const Type &outtype) const;

        /// Tries to get a string representation of the underlying value.
        /// This requires the value's type to have a ReaderWriter object
        /// associated to it. If the conversion can't be completed, an
        /// exception is thrown.
        std::string toString() const;
        
        /// Swaps the content of this Value with another Value
        void swap(Value &v);


    private:
        // It's good to have friends!
        template<typename T> friend T variant_cast(const Value &v);
        template<typename T> friend bool requires_conversion(const Value &v);
        template<typename T> friend T *extract_raw_data(Value &v);
        template<typename T> friend const T *extract_raw_data(const Value &v);

        // throw an exception if the value is empty
        void check_empty() const;

        // Base class for holding values. Provides a clone() method
        // which must be overriden in descendant classes.
        struct Instance_base  
        { 
            virtual Instance_base *clone() const = 0;
            virtual ~Instance_base() {} 
        };

        // Generic descendant of Instance_base for holding values of
        // type T. Note that values are created on the stack.
        template<typename T>
        struct Instance: Instance_base
        {
            Instance(T data): data_(data) {}
            virtual Instance_base *clone() const { return new Instance<T>(*this); }
            virtual ~Instance() {}
            T data_;
        };

        // Base class for storage of Instance objects. Actually three
        // instances are created: the main instance which keeps the
        // desired value, an additional instance that keeps a reference
        // to that value, and another instance that keeps a const
        // reference to that value. These additional instances are queried 
        // when casting the Value to a reference type.
        struct Instance_box_base
        {
            Instance_box_base()
            :    inst_(0),
                ref_inst_(0),
                const_ref_inst_(0)
            {
            }

            virtual ~Instance_box_base()
            {
                delete inst_;
                delete ref_inst_;
                delete const_ref_inst_;
            }

            // clones the instance box
            virtual Instance_box_base *clone() const = 0;
            // returns the type of the value held
            virtual const Type *type() const = 0;
            // returns the actual pointed type if applicable
            virtual const Type *ptype() const { return 0; }
            // returns whether the data is a null pointer
            virtual bool nullptr() const = 0;

            Instance_base *inst_;
            Instance_base *ref_inst_;
            Instance_base *const_ref_inst_;
        };

        // Generic instance box for non-pointer values.
        template<typename T>
        struct Instance_box: Instance_box_base
        {
            Instance_box(): Instance_box_base(), nullptr_(false) {}

            Instance_box(const T &d, bool nullptr = false)
            :    Instance_box_base(),
                nullptr_(nullptr)
            {
                Instance<T> *vl = new Instance<T>(d);
                inst_ = vl;
                ref_inst_ = new Instance<T &>(vl->data_);
                const_ref_inst_ = new Instance<const T &>(vl->data_);
            }

            virtual Instance_box_base *clone() const
            {
                Instance_box<T> *new_inbox = new Instance_box<T>();

                // ??? this static_cast<> shouldn't be necessary, but the 
                // MSVC++ compiler complains about invalid casting without it!
                Instance<T> *vl = static_cast<Instance<T> *>(inst_->clone());
                
                new_inbox->inst_ = vl;
                new_inbox->ref_inst_ = new Instance<T &>(vl->data_);
                new_inbox->const_ref_inst_ = new Instance<const T &>(vl->data_);
                new_inbox->nullptr_ = nullptr_;
                return new_inbox;
            }

            virtual const Type *type() const
            {
                return &typeof(static_cast<Instance<T> *>(inst_)->data_);
            }

            virtual bool nullptr() const
            {
                return nullptr_;
            }

        private:
            bool nullptr_;
        };

        // Generic instance box for pointer values. Unlike Instance_box<>, 
        // this struct template provides a ptype() method that unreferences
        // the pointer (T is supposed to be a pointer) and gets its actual
        // type.
        template<typename T>
        struct Ptr_instance_box: Instance_box_base
        {
            Ptr_instance_box(): Instance_box_base() {}

            Ptr_instance_box(const T &d)
            :    Instance_box_base()
            {
                Instance<T> *vl = new Instance<T>(d);
                inst_ = vl;
                ref_inst_ = new Instance<T &>(vl->data_);
                const_ref_inst_ = new Instance<const T &>(vl->data_);
            }

            virtual Instance_box_base *clone() const
            {
                Ptr_instance_box<T> *new_inbox = new Ptr_instance_box<T>();

                // ??? this static_cast<> shouldn't be necessary, but the 
                // MSVC++ compiler complains about invalid casting without it!
                Instance<T> *vl = static_cast<Instance<T> *>(inst_->clone());
                
                new_inbox->inst_ = vl;
                new_inbox->ref_inst_ = new Instance<T &>(vl->data_);
                new_inbox->const_ref_inst_ = new Instance<const T &>(vl->data_);
                return new_inbox;
            }

            virtual const Type *type() const
            {
                return &typeof(static_cast<Instance<T> *>(inst_)->data_);
            }

            virtual const Type *ptype() const
            {
                if (!static_cast<Instance<T> *>(inst_)->data_) return 0;
                return &typeof(*static_cast<Instance<T> *>(inst_)->data_);
            }

            virtual bool nullptr() const
            {
                return static_cast<Instance<T> *>(inst_)->data_ == 0;
            }

        };

        Instance_box_base *inbox_;
        const Type *type_;
        const Type *ptype_;
    };

    /// A vector of values.
    typedef std::vector<Value> ValueList;
    
    
    // INLINE METHODS

    inline Value::Value()
    :    inbox_(0),
        type_(&Reflection::type_void()),
        ptype_(0)
    {
    }

    template<typename T> Value::Value(const T &v)
    :    ptype_(0)
    {
        inbox_ = new Instance_box<T>(v);
        type_ = inbox_->type();
    }

    inline Value::Value(const void *v)
    :    ptype_(0)
    {
        inbox_ = new Instance_box<const void *>(v, v == 0);
        type_ = inbox_->type();
    }

    inline Value::Value(void *v)
    :    ptype_(0)
    {
        inbox_ = new Instance_box<void *>(v, v == 0);
        type_ = inbox_->type();
    }

    template<typename T> Value::Value(const T *v)
    {
        inbox_ = new Ptr_instance_box<const T *>(v);
        type_ = inbox_->type();
        ptype_ = inbox_->ptype();
    }

    template<typename T> Value::Value(T *v)
    {
        inbox_ = new Ptr_instance_box<T *>(v);
        type_ = inbox_->type();
        ptype_ = inbox_->ptype();
    }

    inline Value::Value(const Value &copy)
    :    inbox_(copy.inbox_? copy.inbox_->clone(): 0),
        type_(copy.type_),
        ptype_(copy.ptype_)
    {
    }

    inline Value &Value::operator=(const Value &copy)
    {
        std::auto_ptr<Instance_box_base> new_inbox(copy.inbox_? copy.inbox_->clone(): 0);
        delete inbox_;
        inbox_ = new_inbox.release();
        type_ = copy.type_;
        ptype_ = copy.ptype_;
        return *this;
    }

    inline Value::~Value()
    {
        delete inbox_;
    }

    inline const Type &Value::getType() const 
    { 
        return *type_; 
    }

    inline const Type &Value::getInstanceType() const
    {
        if (ptype_)
            return *ptype_;
        return *type_;
    }

    inline bool Value::isTypedPointer() const
    {
        return ptype_ != 0;
    }

    inline bool Value::isEmpty() const
    {
        return inbox_ == 0;
    }

    inline bool Value::isNullPointer() const
    {
        return inbox_->nullptr();
    }

}

#endif