libki/include/ki/pclass/VectorProperty.h

392 lines
10 KiB
C++

#pragma once
#include <vector>
#include "ki/pclass/Property.h"
#include "ki/util/exception.h"
namespace ki
{
namespace pclass
{
// Forward declare for our helpers
template <typename ValueT>
class VectorProperty;
/// @cond DOXYGEN_SKIP
/**
* A helper utility that provides the right implementation of copy(),
* get_object() and set_object(), based on characteristics of type: ValueT.
*/
template <
typename ValueT,
typename IsPointerEnable = void,
typename IsBaseEnable = void
>
struct vector_value_object_helper
{
static ValueT copy(VectorProperty<ValueT> &prop, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// In cases where ValueT is not a pointer, and does not derive from PropertyClass,
// just call the copy constructor.
return ValueT(prop.at(index));
}
static const PropertyClass *get_object(const VectorProperty<ValueT> &prop, const int index)
{
// ValueT does not derive from PropertyClass, and so, this property is not
// storing an object.
throw runtime_error(
"Tried calling get_object() on a property that does not store an object."
);
}
static void set_object(VectorProperty<ValueT> &prop,
std::unique_ptr<PropertyClass> &object, const int index)
{
// ValueT does not derive from PropertyClass, and so, this property is not
// storing an object.
throw runtime_error(
"Tried calling set_object() on a property that does not store an object."
);
}
};
/**
*
*/
template <typename ValueT>
struct vector_value_object_helper<
ValueT,
typename std::enable_if<
std::is_pointer<ValueT>::value
>::type,
typename std::enable_if<
!std::is_base_of<
PropertyClass,
typename std::remove_pointer<ValueT>::type
>::value
>::type
>
{
static ValueT copy(VectorProperty<ValueT> &prop, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// The copy constructor for all pointers is to copy the pointer
// without creating a new copy of the object it's pointing to.
return prop.at(index);
}
static const PropertyClass *get_object(const VectorProperty<ValueT> &prop, const int index)
{
// ValueT does not derive from PropertyClass, and so, this property is not
// storing an object.
throw runtime_error(
"Tried calling get_object() on a property that does not store an object."
);
}
static void set_object(VectorProperty<ValueT> &prop,
std::unique_ptr<PropertyClass> &object, const int index)
{
// ValueT does not derive from PropertyClass, and so, this property is not
// storing an object.
throw runtime_error(
"Tried calling set_object() on a property that does not store an object."
);
}
};
/**
*
*/
template <typename ValueT>
struct vector_value_object_helper<
ValueT,
typename std::enable_if<
std::is_pointer<ValueT>::value
>::type,
typename std::enable_if<
std::is_base_of<
PropertyClass,
typename std::remove_pointer<ValueT>::type
>::value
>::type
>
{
static ValueT copy(VectorProperty<ValueT> &prop, const int index)
{
// The copy constructor for all pointers is to copy the pointer
// without creating a new copy of the object it's pointing to.
return prop.at(index);
}
static const PropertyClass *get_object(const VectorProperty<ValueT> &prop, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// ValueT does derive from PropertyClass, and we have a pointer to an instance
// of ValueT, so we can cast down to a PropertyClass pointer.
return dynamic_cast<PropertyClass *>(prop.at(index));
}
static void set_object(VectorProperty<ValueT> &prop,
std::unique_ptr<PropertyClass> &object, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// Ensure that object inherits the type of the property
if (object)
assert_type_match(prop.get_type(), object->get_type(), true);
// ValueT does derive from PropertyClass, and we have a pointer to an instance
// of PropertyClass, so cast the pointer up to a ValueT.
prop.at(index) = dynamic_cast<ValueT>(object.release());
}
};
/**
*
*/
template <typename ValueT>
struct vector_value_object_helper<
ValueT,
typename std::enable_if<
!std::is_pointer<ValueT>::value
>::type,
typename std::enable_if<
std::is_base_of<
PropertyClass,
typename std::remove_pointer<ValueT>::type
>::value
>::type
>
{
static ValueT copy(VectorProperty<ValueT> &prop, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// Derivitives of PropertyClass implement a clone method that returns
// a pointer to a copy.
ValueT *value_ptr = dynamic_cast<ValueT *>(prop.at(index).copy());
ValueT value = *value_ptr;
delete value_ptr;
return value;
}
static const PropertyClass *get_object(const VectorProperty<ValueT> &prop, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// ValueT does derive from PropertyClass, and we have an instance of ValueT,
// so we can cast down to a PropertyClass pointer.
return dynamic_cast<const PropertyClass *>(&prop.at(index));
}
static void set_object(VectorProperty<ValueT> &prop,
std::unique_ptr<PropertyClass> &object, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
// Ensure that object is not nullptr
if (!object)
throw runtime_error("Value cannot be null.");
// Ensure that object is exactly the type of the property
assert_type_match(prop.get_type(), object->get_type());
// ValueT does derive from PropertyClass, but we don't store a pointer,
// so we need to copy the value in.
prop.at(index) = *dynamic_cast<ValueT *>(object.get());
}
};
/**
*
*/
template <
typename ValueT,
typename IsPointerEnable = void
>
struct vector_value_rw_helper
{
static void write_value_to(const VectorProperty<ValueT> &prop, BitStream &stream, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
prop.get_type().write_to(
stream,
Value::make_reference<ValueT>(prop.at(index))
);
}
static void read_value_from(VectorProperty<ValueT> &prop, BitStream &stream, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
Value value = prop.get_type().read_from(stream);
prop.at(index) = value.get<ValueT>();
}
};
/**
*
*/
template <typename ValueT>
struct vector_value_rw_helper<
ValueT,
typename std::enable_if<std::is_pointer<ValueT>::value>::type
>
{
using type = typename std::remove_pointer<ValueT>::type;
static void write_value_to(const VectorProperty<ValueT> &prop, BitStream &stream, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
prop.get_type().write_to(
stream,
Value::make_reference<type>(*prop.at(index))
);
}
static void read_value_from(VectorProperty<ValueT> &prop, BitStream &stream, const int index)
{
// Ensure index is within bounds
if (index < 0 || index >= prop.size())
throw runtime_error("Index out of bounds.");
Value value = prop.get_type().read_from(stream);
ValueT &value_ref = prop.at(index);
value_ref = value.take<type>();
}
};
/**
*
*/
template <typename ValueT>
struct vector_value_helper
{
static ValueT copy(VectorProperty<ValueT> &prop, const int index)
{
return vector_value_object_helper<ValueT>::copy(prop, index);
}
static const PropertyClass *get_object(const VectorProperty<ValueT> &prop,
const int index)
{
return vector_value_object_helper<ValueT>::get_object(prop, index);
}
static void set_object(VectorProperty<ValueT> &prop,
std::unique_ptr<PropertyClass> &object, const int index)
{
vector_value_object_helper<ValueT>::set_object(prop, object, index);
}
static void write_value_to(const VectorProperty<ValueT> &prop,
BitStream &stream, const int index)
{
vector_value_rw_helper<ValueT>::write_value_to(prop, stream, index);
}
static void read_value_from(VectorProperty<ValueT> &prop,
BitStream &stream, const int index)
{
vector_value_rw_helper<ValueT>::read_value_from(prop, stream, index);
}
};
/// @endcond
/**
*
*/
template <typename ValueT>
class VectorProperty : public std::vector<ValueT>, public IDynamicProperty
{
public:
// Do not allow copy assignment. Once a property has been constructed,
// it shouldn't be able to change.
VectorProperty<ValueT> &operator=(const VectorProperty<ValueT> &that) = delete;
VectorProperty(PropertyClass &object,
const std::string &name, const Type &type)
: IDynamicProperty(object, name, type)
{}
VectorProperty(PropertyClass &object,
const VectorProperty<ValueT> &that)
: IDynamicProperty(object, that)
{
// Copy vector values into this vector
for (auto i = 0; i < this->size(); i++)
this->push_back(vector_value_helper<ValueT>::copy(*this, i));
}
constexpr bool is_pointer() const override
{
return std::is_pointer<ValueT>::value;
}
std::size_t get_element_count() const override
{
return this->size();
}
void set_element_count(const std::size_t size) override
{
this->resize(size);
}
Value get_value(int index) const override
{
if (index < 0 || index >= this->size())
throw runtime_error("Index out of bounds.");
return Value::make_reference(this->at(index));
}
const PropertyClass *get_object(const int index) const override
{
return vector_value_helper<ValueT>::get_object(*this, index);
}
void set_object(std::unique_ptr<PropertyClass> &object, int index) override
{
return vector_value_helper<ValueT>::set_object(*this, object, index);
}
void write_value_to(BitStream &stream, const int index) const override
{
vector_value_helper<ValueT>::write_value_to(*this, stream, index);
}
void read_value_from(BitStream &stream, const int index) override
{
vector_value_helper<ValueT>::read_value_from(*this, stream, index);
}
};
}
}