framework/randomshaders/rsgVariableValue.hpp - third_party/vulkan-cts - Git at Google

 #ifndef _RSGVARIABLEVALUE_HPP
 #define _RSGVARIABLEVALUE_HPP
 /*-------------------------------------------------------------------------
  * drawElements Quality Program Random Shader Generator
  * ----------------------------------------------------
  *
  * Copyright 2014 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *//*!
  * \file
  * \brief Variable Value class.
  *//*--------------------------------------------------------------------*/

 #include "rsgDefs.hpp"
 #include "rsgVariableType.hpp"
 #include "rsgVariable.hpp"
 #include "tcuVector.hpp"

 #include <algorithm>

 namespace rsg
 {

 union Scalar
 {
 	int		intVal;
 	float	floatVal;
 	bool	boolVal;

 	Scalar (void)		: intVal	(0) {}
 	Scalar (float v)	: floatVal	(v) {}
 	Scalar (int v)		: intVal	(v) {}
 	Scalar (bool v)		: boolVal	(v) {}

 	// Bit-exact compare
 	bool operator== (Scalar other) const { return intVal == other.intVal; }
 	bool operator!= (Scalar other) const { return intVal != other.intVal; }

 	template <typename T> static Scalar min	(void);
 	template <typename T> static Scalar max	(void);

 	template <typename T> T		as (void) const;
 	template <typename T> T&	as (void);
 };
 DE_STATIC_ASSERT(sizeof(Scalar) == sizeof(deUint32));

 template <> inline Scalar Scalar::min<float>	(void)	{ return Scalar((int)0xff800000);	}
 template <> inline Scalar Scalar::max<float>	(void)	{ return Scalar((int)0x7f800000);	}
 template <> inline Scalar Scalar::min<int>		(void)	{ return Scalar((int)0x80000000);	}
 template <> inline Scalar Scalar::max<int>		(void)	{ return Scalar((int)0x7fffffff);	}
 template <> inline Scalar Scalar::min<bool>		(void)	{ return Scalar(false);				}
 template <> inline Scalar Scalar::max<bool>		(void)	{ return Scalar(true);				}

 template <> inline float	Scalar::as<float>	(void) const	{ return floatVal;	}
 template <> inline float&	Scalar::as<float>	(void)			{ return floatVal;	}
 template <> inline int		Scalar::as<int>		(void) const	{ return intVal;	}
 template <> inline int&		Scalar::as<int>		(void)			{ return intVal;	}
 template <> inline bool		Scalar::as<bool>	(void) const	{ return boolVal;	}
 template <> inline bool&	Scalar::as<bool>	(void)			{ return boolVal;	}

 template <int Stride>
 class StridedValueRead
 {
 public:
 								StridedValueRead		(const VariableType& type, const Scalar* value) : m_type(type), m_value(value) {}

 	const VariableType&			getType					(void) const			{ return m_type;	}
 	const Scalar*				getValuePtr				(void) const			{ return m_value;	}

 private:
 	const VariableType&			m_type;
 	const Scalar*				m_value;
 };

 template <int Stride>
 class ConstStridedValueAccess
 {
 public:
 								ConstStridedValueAccess	(void) : m_type(DE_NULL), m_value(DE_NULL) {}
 								ConstStridedValueAccess	(const VariableType& type, const Scalar* valuePtr) : m_type(&type), m_value(const_cast<Scalar*>(valuePtr)) {}

 	const VariableType&			getType					(void) const			{ return *m_type;			}

 	// Read-only access
 	ConstStridedValueAccess		component				(int compNdx) const		{ return ConstStridedValueAccess(getType().getElementType(), m_value + Stride*compNdx);													}
 	ConstStridedValueAccess		arrayElement			(int elementNdx) const	{ return ConstStridedValueAccess(getType().getElementType(), m_value + Stride*getType().getElementScalarOffset(elementNdx));				}
 	ConstStridedValueAccess		member					(int memberNdx) const	{ return ConstStridedValueAccess(getType().getMembers()[memberNdx].getType(), m_value + Stride*getType().getMemberScalarOffset(memberNdx));	}

 	float						asFloat					(void) const			{ DE_STATIC_ASSERT(Stride == 1); return m_value->floatVal;	}
 	int							asInt					(void) const			{ DE_STATIC_ASSERT(Stride == 1); return m_value->intVal;	}
 	bool						asBool					(void) const			{ DE_STATIC_ASSERT(Stride == 1); return m_value->boolVal;	}
 	Scalar						asScalar				(void) const			{ DE_STATIC_ASSERT(Stride == 1); return *m_value;			}

 	float						asFloat					(int ndx) const			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx].floatVal;	}
 	int							asInt					(int ndx) const			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx].intVal;	}
 	bool						asBool					(int ndx) const			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx].boolVal;	}
 	Scalar						asScalar				(int ndx) const			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx];			}

 	template <typename T>
 	T							as						(int ndx) const			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].template as<T>();	}

 	// For assignment: b = a.value()
 	StridedValueRead<Stride>	value					(void) const			{ return StridedValueRead<Stride>(getType(), m_value);		}

 protected:
 	const VariableType*			m_type;
 	Scalar*						m_value;	// \note Non-const internal pointer is used so that ValueAccess can extend this class with RW access
 };

 template <int Stride>
 class StridedValueAccess : public ConstStridedValueAccess<Stride>
 {
 public:
 								StridedValueAccess	(void) {}
 								StridedValueAccess	(const VariableType& type, Scalar* valuePtr) : ConstStridedValueAccess<Stride>(type, valuePtr) {}

 	// Read-write access
 	StridedValueAccess			component			(int compNdx)		{ return StridedValueAccess(this->getType().getElementType(), this->m_value + Stride*compNdx);													}
 	StridedValueAccess			arrayElement		(int elementNdx)	{ return StridedValueAccess(this->getType().getElementType(), this->m_value + Stride*this->getType().getElementScalarOffset(elementNdx));					}
 	StridedValueAccess			member				(int memberNdx)		{ return StridedValueAccess(this->getType().getMembers()[memberNdx].getType(), this->m_value + Stride*this->getType().getMemberScalarOffset(memberNdx));	}

 	float&						asFloat				(void)				{ DE_STATIC_ASSERT(Stride == 1); return this->m_value->floatVal;	}
 	int&						asInt				(void)				{ DE_STATIC_ASSERT(Stride == 1); return this->m_value->intVal;		}
 	bool&						asBool				(void)				{ DE_STATIC_ASSERT(Stride == 1); return this->m_value->boolVal;		}
 	Scalar&						asScalar			(void)				{ DE_STATIC_ASSERT(Stride == 1); return *this->m_value;				}

 	float&						asFloat				(int ndx)			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].floatVal;	}
 	int&						asInt				(int ndx)			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].intVal;		}
 	bool&						asBool				(int ndx)			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].boolVal;		}
 	Scalar&						asScalar			(int ndx)			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx];				}

 	template <typename T>
 	T&							as					(int ndx)			{ DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].template as<T>();		}

 	template <int SrcStride>
 	StridedValueAccess&			operator=			(const StridedValueRead<SrcStride>& value);

 	// Helpers, work only in Stride == 1 case
 	template <int Size>
 	StridedValueAccess&			operator=			(const tcu::Vector<float, Size>& vec);
 	StridedValueAccess&			operator=			(float floatVal)	{ asFloat()		= floatVal;	return *this;	}
 	StridedValueAccess&			operator=			(int intVal)		{ asInt()		= intVal;	return *this;	}
 	StridedValueAccess&			operator=			(bool boolVal)		{ asBool()		= boolVal;	return *this;	}
 	StridedValueAccess&			operator=			(Scalar val)		{ asScalar()	= val;		return *this;	}
 };

 template <int Stride>
 template <int SrcStride>
 StridedValueAccess<Stride>& StridedValueAccess<Stride>::operator= (const StridedValueRead<SrcStride>& valueRead)
 {
 	DE_STATIC_ASSERT(SrcStride == Stride || SrcStride == 1);
 	DE_ASSERT(this->getType() == valueRead.getType());

 	int scalarSize = this->getType().getScalarSize();

 	if (scalarSize == 0)
 		return *this; // Happens when void value range is copied

 	if (Stride == SrcStride)
 		std::copy(valueRead.getValuePtr(), valueRead.getValuePtr() + scalarSize*Stride, this->m_value);
 	else
 	{
 		for (int scalarNdx = 0; scalarNdx < scalarSize; scalarNdx++)
 			std::fill(this->m_value + scalarNdx*Stride, this->m_value + (scalarNdx+1)*Stride, valueRead.getValuePtr()[scalarNdx]);
 	}

 	return *this;
 }

 template <int Stride>
 template <int Size>
 StridedValueAccess<Stride>& StridedValueAccess<Stride>::operator= (const tcu::Vector<float, Size>& vec)
 {
 	DE_ASSERT(this->getType() == VariableType(VariableType::TYPE_FLOAT, Size));
 	for (int comp = 0; comp < 4; comp++)
 		component(comp).asFloat() = vec.getPtr()[comp];

 	return *this;
 }

 // Typedefs for stride == 1 case
 typedef ConstStridedValueAccess<1>	ConstValueAccess;
 typedef StridedValueAccess<1>		ValueAccess;

 class ConstValueRangeAccess
 {
 public:
 								ConstValueRangeAccess	(void) : m_type(DE_NULL), m_min(DE_NULL), m_max(DE_NULL) {}
 								ConstValueRangeAccess	(const VariableType& type, const Scalar* minVal, const Scalar* maxVal) : m_type(&type), m_min(const_cast<Scalar*>(minVal)), m_max(const_cast<Scalar*>(maxVal)) {}

 	const VariableType&			getType					(void) const	{ return *m_type;							}
 	ConstValueAccess			getMin					(void) const	{ return ConstValueAccess(*m_type, m_min);	}
 	ConstValueAccess			getMax					(void) const	{ return ConstValueAccess(*m_type, m_max);	}

 	// Read-only access
 	ConstValueRangeAccess		component				(int compNdx) const;
 	ConstValueRangeAccess		arrayElement			(int elementNdx) const;
 	ConstValueRangeAccess		member					(int memberNdx) const;

 	// Set operations - tests condition for all elements
 	bool						intersects				(const ConstValueRangeAccess& other) const;
 	bool						isSupersetOf			(const ConstValueRangeAccess& other) const;
 	bool						isSubsetOf				(const ConstValueRangeAccess& other) const;

 protected:
 	const VariableType*			m_type;
 	Scalar*						m_min;	// \note See note in ConstValueAccess
 	Scalar*						m_max;
 };

 inline ConstValueRangeAccess ConstValueRangeAccess::component (int compNdx) const
 {
 	return ConstValueRangeAccess(m_type->getElementType(), m_min + compNdx, m_max + compNdx);
 }

 inline ConstValueRangeAccess ConstValueRangeAccess::arrayElement (int elementNdx) const
 {
 	int offset = m_type->getElementScalarOffset(elementNdx);
 	return ConstValueRangeAccess(m_type->getElementType(), m_min + offset, m_max + offset);
 }

 inline ConstValueRangeAccess ConstValueRangeAccess::member (int memberNdx) const
 {
 	int offset = m_type->getMemberScalarOffset(memberNdx);
 	return ConstValueRangeAccess(m_type->getMembers()[memberNdx].getType(), m_min + offset, m_max + offset);
 }

 class ValueRangeAccess : public ConstValueRangeAccess
 {
 public:
 								ValueRangeAccess		(const VariableType& type, Scalar* minVal, Scalar* maxVal) : ConstValueRangeAccess(type, minVal, maxVal) {}

 	// Read-write access
 	ValueAccess					getMin					(void) { return ValueAccess(*m_type, m_min);	}
 	ValueAccess					getMax					(void) { return ValueAccess(*m_type, m_max);	}

 	ValueRangeAccess			component				(int compNdx);
 	ValueRangeAccess			arrayElement			(int elementNdx);
 	ValueRangeAccess			member					(int memberNdx);
 };

 inline ValueRangeAccess ValueRangeAccess::component (int compNdx)
 {
 	return ValueRangeAccess(m_type->getElementType(), m_min + compNdx, m_max + compNdx);
 }

 inline ValueRangeAccess ValueRangeAccess::arrayElement (int elementNdx)
 {
 	int offset = m_type->getElementScalarOffset(elementNdx);
 	return ValueRangeAccess(m_type->getElementType(), m_min + offset, m_max + offset);
 }

 inline ValueRangeAccess ValueRangeAccess::member (int memberNdx)
 {
 	int offset = m_type->getMemberScalarOffset(memberNdx);
 	return ValueRangeAccess(m_type->getMembers()[memberNdx].getType(), m_min + offset, m_max + offset);
 }

 class ValueRange
 {
 public:
 								ValueRange			(const VariableType& type);
 								ValueRange			(const VariableType& type, const ConstValueAccess& minVal, const ConstValueAccess& maxVal);
 								ValueRange			(const VariableType& type, const Scalar* minVal, const Scalar* maxVal);
 								ValueRange			(ConstValueRangeAccess other);
 								~ValueRange			(void);

 	const VariableType&			getType				(void) const	{ return m_type;								}

 	ValueAccess					getMin				(void)			{ return ValueAccess(m_type, getMinPtr());		}
 	ValueAccess					getMax				(void)			{ return ValueAccess(m_type, getMaxPtr());		}

 	ConstValueAccess			getMin				(void) const	{ return ConstValueAccess(m_type, getMinPtr());	}
 	ConstValueAccess			getMax				(void) const	{ return ConstValueAccess(m_type, getMaxPtr());	}

 	ValueRangeAccess			asAccess			(void)			{ return ValueRangeAccess(m_type, getMinPtr(), getMaxPtr());		}
 	ConstValueRangeAccess		asAccess			(void) const	{ return ConstValueRangeAccess(m_type, getMinPtr(), getMaxPtr());	}

 	operator ConstValueRangeAccess					(void) const	{ return asAccess();							}
 	operator ValueRangeAccess						(void)			{ return asAccess();							}

 	static void					computeIntersection	(ValueRangeAccess dst, const ConstValueRangeAccess& a, const ConstValueRangeAccess& b);
 	static void					computeIntersection	(ValueRange& dst, const ConstValueRangeAccess& a, const ConstValueRangeAccess& b);

 private:
 	const Scalar*				getMinPtr			(void) const	{ return m_min.empty() ? DE_NULL : &m_min[0];	}
 	const Scalar*				getMaxPtr			(void) const	{ return m_max.empty() ? DE_NULL : &m_max[0];	}

 	Scalar*						getMinPtr			(void)			{ return m_min.empty() ? DE_NULL : &m_min[0];	}
 	Scalar*						getMaxPtr			(void)			{ return m_max.empty() ? DE_NULL : &m_max[0];	}

 	VariableType				m_type;
 	std::vector<Scalar>			m_min;
 	std::vector<Scalar>			m_max;
 };

 template <int Stride>
 class ValueStorage
 {
 public:
 										ValueStorage		(void);
 										ValueStorage		(const VariableType& type);

 	void								setStorage			(const VariableType& type);

 	StridedValueAccess<Stride>			getValue			(const VariableType& type)			{ return StridedValueAccess<Stride>(type, &m_value[0]);			}
 	ConstStridedValueAccess<Stride>		getValue			(const VariableType& type) const	{ return ConstStridedValueAccess<Stride>(type, &m_value[0]);	}

 private:
 										ValueStorage		(const ValueStorage& other);
 	ValueStorage						operator=			(const ValueStorage& other);

 	std::vector<Scalar>					m_value;
 };

 template <int Stride>
 ValueStorage<Stride>::ValueStorage (void)
 {
 }

 template <int Stride>
 ValueStorage<Stride>::ValueStorage (const VariableType& type)
 {
 	setStorage(type);
 }

 template <int Stride>
 void ValueStorage<Stride>::setStorage (const VariableType& type)
 {
 	m_value.resize(type.getScalarSize() * Stride);
 }

 class VariableValue
 {
 public:
 							VariableValue		(const Variable* variable) : m_variable(variable), m_storage(m_variable->getType()) {}
 							~VariableValue		(void) {}

 	const Variable*			getVariable			(void) const	{ return m_variable;								}
 	ValueAccess				getValue			(void)			{ return m_storage.getValue(m_variable->getType());	}
 	ConstValueAccess		getValue			(void) const	{ return m_storage.getValue(m_variable->getType());	}

 							VariableValue		(const VariableValue& other);
 	VariableValue&			operator=			(const VariableValue& other);

 private:
 	const VariableType&		getType				(void) const	{ return m_variable->getType();						}

 	const Variable*			m_variable;
 	ValueStorage<1>			m_storage;
 };

 } // rsg

 #endif // _RSGVARIABLEVALUE_HPP
	#ifndef _RSGVARIABLEVALUE_HPP
	#define _RSGVARIABLEVALUE_HPP
	/*-------------------------------------------------------------------------
	* drawElements Quality Program Random Shader Generator
	* ----------------------------------------------------
	*
	* Copyright 2014 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	//!
	* \file
	* \brief Variable Value class.
	//--------------------------------------------------------------------*/

	#include "rsgDefs.hpp"
	#include "rsgVariableType.hpp"
	#include "rsgVariable.hpp"
	#include "tcuVector.hpp"

	#include <algorithm>

	namespace rsg
	{

	union Scalar
	{
	int intVal;
	float floatVal;
	bool boolVal;

	Scalar (void) : intVal (0) {}
	Scalar (float v) : floatVal (v) {}
	Scalar (int v) : intVal (v) {}
	Scalar (bool v) : boolVal (v) {}

	// Bit-exact compare
	bool operator== (Scalar other) const { return intVal == other.intVal; }
	bool operator!= (Scalar other) const { return intVal != other.intVal; }

	template <typename T> static Scalar min (void);
	template <typename T> static Scalar max (void);

	template <typename T> T as (void) const;
	template <typename T> T& as (void);
	};
	DE_STATIC_ASSERT(sizeof(Scalar) == sizeof(deUint32));

	template <> inline Scalar Scalar::min<float> (void) { return Scalar((int)0xff800000); }
	template <> inline Scalar Scalar::max<float> (void) { return Scalar((int)0x7f800000); }
	template <> inline Scalar Scalar::min<int> (void) { return Scalar((int)0x80000000); }
	template <> inline Scalar Scalar::max<int> (void) { return Scalar((int)0x7fffffff); }
	template <> inline Scalar Scalar::min<bool> (void) { return Scalar(false); }
	template <> inline Scalar Scalar::max<bool> (void) { return Scalar(true); }

	template <> inline float Scalar::as<float> (void) const { return floatVal; }
	template <> inline float& Scalar::as<float> (void) { return floatVal; }
	template <> inline int Scalar::as<int> (void) const { return intVal; }
	template <> inline int& Scalar::as<int> (void) { return intVal; }
	template <> inline bool Scalar::as<bool> (void) const { return boolVal; }
	template <> inline bool& Scalar::as<bool> (void) { return boolVal; }

	template <int Stride>
	class StridedValueRead
	{
	public:
	StridedValueRead (const VariableType& type, const Scalar* value) : m_type(type), m_value(value) {}

	const VariableType& getType (void) const { return m_type; }
	const Scalar* getValuePtr (void) const { return m_value; }

	private:
	const VariableType& m_type;
	const Scalar* m_value;
	};

	template <int Stride>
	class ConstStridedValueAccess
	{
	public:
	ConstStridedValueAccess (void) : m_type(DE_NULL), m_value(DE_NULL) {}
	ConstStridedValueAccess (const VariableType& type, const Scalar* valuePtr) : m_type(&type), m_value(const_cast<Scalar*>(valuePtr)) {}

	const VariableType& getType (void) const { return *m_type; }

	// Read-only access
	ConstStridedValueAccess component (int compNdx) const { return ConstStridedValueAccess(getType().getElementType(), m_value + Stride*compNdx); }
	ConstStridedValueAccess arrayElement (int elementNdx) const { return ConstStridedValueAccess(getType().getElementType(), m_value + Stride*getType().getElementScalarOffset(elementNdx)); }
	ConstStridedValueAccess member (int memberNdx) const { return ConstStridedValueAccess(getType().getMembers()[memberNdx].getType(), m_value + Stride*getType().getMemberScalarOffset(memberNdx)); }

	float asFloat (void) const { DE_STATIC_ASSERT(Stride == 1); return m_value->floatVal; }
	int asInt (void) const { DE_STATIC_ASSERT(Stride == 1); return m_value->intVal; }
	bool asBool (void) const { DE_STATIC_ASSERT(Stride == 1); return m_value->boolVal; }
	Scalar asScalar (void) const { DE_STATIC_ASSERT(Stride == 1); return *m_value; }

	float asFloat (int ndx) const { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx].floatVal; }
	int asInt (int ndx) const { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx].intVal; }
	bool asBool (int ndx) const { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx].boolVal; }
	Scalar asScalar (int ndx) const { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return m_value[ndx]; }

	template <typename T>
	T as (int ndx) const { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].template as<T>(); }

	// For assignment: b = a.value()
	StridedValueRead<Stride> value (void) const { return StridedValueRead<Stride>(getType(), m_value); }

	protected:
	const VariableType* m_type;
	Scalar* m_value; // \note Non-const internal pointer is used so that ValueAccess can extend this class with RW access
	};

	template <int Stride>
	class StridedValueAccess : public ConstStridedValueAccess<Stride>
	{
	public:
	StridedValueAccess (void) {}
	StridedValueAccess (const VariableType& type, Scalar* valuePtr) : ConstStridedValueAccess<Stride>(type, valuePtr) {}

	// Read-write access
	StridedValueAccess component (int compNdx) { return StridedValueAccess(this->getType().getElementType(), this->m_value + Stride*compNdx); }
	StridedValueAccess arrayElement (int elementNdx) { return StridedValueAccess(this->getType().getElementType(), this->m_value + Stride*this->getType().getElementScalarOffset(elementNdx)); }
	StridedValueAccess member (int memberNdx) { return StridedValueAccess(this->getType().getMembers()[memberNdx].getType(), this->m_value + Stride*this->getType().getMemberScalarOffset(memberNdx)); }

	float& asFloat (void) { DE_STATIC_ASSERT(Stride == 1); return this->m_value->floatVal; }
	int& asInt (void) { DE_STATIC_ASSERT(Stride == 1); return this->m_value->intVal; }
	bool& asBool (void) { DE_STATIC_ASSERT(Stride == 1); return this->m_value->boolVal; }
	Scalar& asScalar (void) { DE_STATIC_ASSERT(Stride == 1); return *this->m_value; }

	float& asFloat (int ndx) { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].floatVal; }
	int& asInt (int ndx) { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].intVal; }
	bool& asBool (int ndx) { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].boolVal; }
	Scalar& asScalar (int ndx) { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx]; }

	template <typename T>
	T& as (int ndx) { DE_ASSERT(de::inBounds(ndx, 0, Stride)); return this->m_value[ndx].template as<T>(); }

	template <int SrcStride>
	StridedValueAccess& operator= (const StridedValueRead<SrcStride>& value);

	// Helpers, work only in Stride == 1 case
	template <int Size>
	StridedValueAccess& operator= (const tcu::Vector<float, Size>& vec);
	StridedValueAccess& operator= (float floatVal) { asFloat() = floatVal; return *this; }
	StridedValueAccess& operator= (int intVal) { asInt() = intVal; return *this; }
	StridedValueAccess& operator= (bool boolVal) { asBool() = boolVal; return *this; }
	StridedValueAccess& operator= (Scalar val) { asScalar() = val; return *this; }
	};

	template <int Stride>
	template <int SrcStride>
	StridedValueAccess<Stride>& StridedValueAccess<Stride>::operator= (const StridedValueRead<SrcStride>& valueRead)
	{
	DE_STATIC_ASSERT(SrcStride == Stride \|\| SrcStride == 1);
	DE_ASSERT(this->getType() == valueRead.getType());

	int scalarSize = this->getType().getScalarSize();

	if (scalarSize == 0)
	return *this; // Happens when void value range is copied

	if (Stride == SrcStride)
	std::copy(valueRead.getValuePtr(), valueRead.getValuePtr() + scalarSize*Stride, this->m_value);
	else
	{
	for (int scalarNdx = 0; scalarNdx < scalarSize; scalarNdx++)
	std::fill(this->m_value + scalarNdxStride, this->m_value + (scalarNdx+1)Stride, valueRead.getValuePtr()[scalarNdx]);
	}

	return *this;
	}

	template <int Stride>
	template <int Size>
	StridedValueAccess<Stride>& StridedValueAccess<Stride>::operator= (const tcu::Vector<float, Size>& vec)
	{
	DE_ASSERT(this->getType() == VariableType(VariableType::TYPE_FLOAT, Size));
	for (int comp = 0; comp < 4; comp++)
	component(comp).asFloat() = vec.getPtr()[comp];

	return *this;
	}

	// Typedefs for stride == 1 case
	typedef ConstStridedValueAccess<1> ConstValueAccess;
	typedef StridedValueAccess<1> ValueAccess;

	class ConstValueRangeAccess
	{
	public:
	ConstValueRangeAccess (void) : m_type(DE_NULL), m_min(DE_NULL), m_max(DE_NULL) {}
	ConstValueRangeAccess (const VariableType& type, const Scalar* minVal, const Scalar* maxVal) : m_type(&type), m_min(const_cast<Scalar>(minVal)), m_max(const_cast<Scalar>(maxVal)) {}

	const VariableType& getType (void) const { return *m_type; }
	ConstValueAccess getMin (void) const { return ConstValueAccess(*m_type, m_min); }
	ConstValueAccess getMax (void) const { return ConstValueAccess(*m_type, m_max); }

	// Read-only access
	ConstValueRangeAccess component (int compNdx) const;
	ConstValueRangeAccess arrayElement (int elementNdx) const;
	ConstValueRangeAccess member (int memberNdx) const;

	// Set operations - tests condition for all elements
	bool intersects (const ConstValueRangeAccess& other) const;
	bool isSupersetOf (const ConstValueRangeAccess& other) const;
	bool isSubsetOf (const ConstValueRangeAccess& other) const;

	protected:
	const VariableType* m_type;
	Scalar* m_min; // \note See note in ConstValueAccess
	Scalar* m_max;
	};

	inline ConstValueRangeAccess ConstValueRangeAccess::component (int compNdx) const
	{
	return ConstValueRangeAccess(m_type->getElementType(), m_min + compNdx, m_max + compNdx);
	}

	inline ConstValueRangeAccess ConstValueRangeAccess::arrayElement (int elementNdx) const
	{
	int offset = m_type->getElementScalarOffset(elementNdx);
	return ConstValueRangeAccess(m_type->getElementType(), m_min + offset, m_max + offset);
	}

	inline ConstValueRangeAccess ConstValueRangeAccess::member (int memberNdx) const
	{
	int offset = m_type->getMemberScalarOffset(memberNdx);
	return ConstValueRangeAccess(m_type->getMembers()[memberNdx].getType(), m_min + offset, m_max + offset);
	}

	class ValueRangeAccess : public ConstValueRangeAccess
	{
	public:
	ValueRangeAccess (const VariableType& type, Scalar* minVal, Scalar* maxVal) : ConstValueRangeAccess(type, minVal, maxVal) {}

	// Read-write access
	ValueAccess getMin (void) { return ValueAccess(*m_type, m_min); }
	ValueAccess getMax (void) { return ValueAccess(*m_type, m_max); }

	ValueRangeAccess component (int compNdx);
	ValueRangeAccess arrayElement (int elementNdx);
	ValueRangeAccess member (int memberNdx);
	};

	inline ValueRangeAccess ValueRangeAccess::component (int compNdx)
	{
	return ValueRangeAccess(m_type->getElementType(), m_min + compNdx, m_max + compNdx);
	}

	inline ValueRangeAccess ValueRangeAccess::arrayElement (int elementNdx)
	{
	int offset = m_type->getElementScalarOffset(elementNdx);
	return ValueRangeAccess(m_type->getElementType(), m_min + offset, m_max + offset);
	}

	inline ValueRangeAccess ValueRangeAccess::member (int memberNdx)
	{
	int offset = m_type->getMemberScalarOffset(memberNdx);
	return ValueRangeAccess(m_type->getMembers()[memberNdx].getType(), m_min + offset, m_max + offset);
	}

	class ValueRange
	{
	public:
	ValueRange (const VariableType& type);
	ValueRange (const VariableType& type, const ConstValueAccess& minVal, const ConstValueAccess& maxVal);
	ValueRange (const VariableType& type, const Scalar* minVal, const Scalar* maxVal);
	ValueRange (ConstValueRangeAccess other);
	~ValueRange (void);

	const VariableType& getType (void) const { return m_type; }

	ValueAccess getMin (void) { return ValueAccess(m_type, getMinPtr()); }
	ValueAccess getMax (void) { return ValueAccess(m_type, getMaxPtr()); }

	ConstValueAccess getMin (void) const { return ConstValueAccess(m_type, getMinPtr()); }
	ConstValueAccess getMax (void) const { return ConstValueAccess(m_type, getMaxPtr()); }

	ValueRangeAccess asAccess (void) { return ValueRangeAccess(m_type, getMinPtr(), getMaxPtr()); }
	ConstValueRangeAccess asAccess (void) const { return ConstValueRangeAccess(m_type, getMinPtr(), getMaxPtr()); }

	operator ConstValueRangeAccess (void) const { return asAccess(); }
	operator ValueRangeAccess (void) { return asAccess(); }

	static void computeIntersection (ValueRangeAccess dst, const ConstValueRangeAccess& a, const ConstValueRangeAccess& b);
	static void computeIntersection (ValueRange& dst, const ConstValueRangeAccess& a, const ConstValueRangeAccess& b);

	private:
	const Scalar* getMinPtr (void) const { return m_min.empty() ? DE_NULL : &m_min[0]; }
	const Scalar* getMaxPtr (void) const { return m_max.empty() ? DE_NULL : &m_max[0]; }

	Scalar* getMinPtr (void) { return m_min.empty() ? DE_NULL : &m_min[0]; }
	Scalar* getMaxPtr (void) { return m_max.empty() ? DE_NULL : &m_max[0]; }

	VariableType m_type;
	std::vector<Scalar> m_min;
	std::vector<Scalar> m_max;
	};

	template <int Stride>
	class ValueStorage
	{
	public:
	ValueStorage (void);
	ValueStorage (const VariableType& type);

	void setStorage (const VariableType& type);

	StridedValueAccess<Stride> getValue (const VariableType& type) { return StridedValueAccess<Stride>(type, &m_value[0]); }
	ConstStridedValueAccess<Stride> getValue (const VariableType& type) const { return ConstStridedValueAccess<Stride>(type, &m_value[0]); }

	private:
	ValueStorage (const ValueStorage& other);
	ValueStorage operator= (const ValueStorage& other);

	std::vector<Scalar> m_value;
	};

	template <int Stride>
	ValueStorage<Stride>::ValueStorage (void)
	{
	}

	template <int Stride>
	ValueStorage<Stride>::ValueStorage (const VariableType& type)
	{
	setStorage(type);
	}

	template <int Stride>
	void ValueStorage<Stride>::setStorage (const VariableType& type)
	{
	m_value.resize(type.getScalarSize() * Stride);
	}

	class VariableValue
	{
	public:
	VariableValue (const Variable* variable) : m_variable(variable), m_storage(m_variable->getType()) {}
	~VariableValue (void) {}

	const Variable* getVariable (void) const { return m_variable; }
	ValueAccess getValue (void) { return m_storage.getValue(m_variable->getType()); }
	ConstValueAccess getValue (void) const { return m_storage.getValue(m_variable->getType()); }

	VariableValue (const VariableValue& other);
	VariableValue& operator= (const VariableValue& other);

	private:
	const VariableType& getType (void) const { return m_variable->getType(); }

	const Variable* m_variable;
	ValueStorage<1> m_storage;
	};

	} // rsg

	#endif // _RSGVARIABLEVALUE_HPP