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

 #ifndef _RSGBUILTINFUNCTIONS_HPP
 #define _RSGBUILTINFUNCTIONS_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 Built-in Functions.
  *//*--------------------------------------------------------------------*/

 #include "rsgDefs.hpp"
 #include "rsgExpression.hpp"
 #include "rsgUtils.hpp"
 #include "deMath.h"

 namespace rsg
 {

 // Template for built-in functions with form "GenType func(GenType val)".
 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 class UnaryBuiltinVecFunc : public Expression
 {
 public:
 								UnaryBuiltinVecFunc		(GeneratorState& state, const char* function, ConstValueRangeAccess valueRange);
 	virtual						~UnaryBuiltinVecFunc	(void);

 	Expression*					createNextChild			(GeneratorState& state);
 	void						tokenize				(GeneratorState& state, TokenStream& str) const;

 	void						evaluate				(ExecutionContext& execCtx);
 	ExecConstValueAccess		getValue				(void) const { return m_value.getValue(m_inValueRange.getType()); }

 	static float				getWeight				(const GeneratorState& state, ConstValueRangeAccess valueRange);

 private:
 	std::string					m_function;
 	ValueRange					m_inValueRange;
 	ExecValueStorage			m_value;
 	Expression*					m_child;
 };

 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::UnaryBuiltinVecFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
 	: m_function		(function)
 	, m_inValueRange	(valueRange.getType())
 	, m_child			(DE_NULL)
 {
 	DE_UNREF(state);
 	DE_ASSERT(valueRange.getType().isFloatOrVec());

 	m_value.setStorage(valueRange.getType());

 	// Compute input value range
 	for (int ndx = 0; ndx < m_inValueRange.getType().getNumElements(); ndx++)
 	{
 		ConstValueRangeAccess	outRange	= valueRange.component(ndx);
 		ValueRangeAccess		inRange		= m_inValueRange.asAccess().component(ndx);

 		ComputeValueRange()(outRange.getMin().asFloat(), outRange.getMax().asFloat(), inRange.getMin().asFloat(), inRange.getMax().asFloat());
 	}
 }

 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::~UnaryBuiltinVecFunc (void)
 {
 	delete m_child;
 }

 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 Expression* UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::createNextChild (GeneratorState& state)
 {
 	if (m_child)
 		return DE_NULL;

 	m_child = Expression::createRandom(state, m_inValueRange.asAccess());
 	return m_child;
 }

 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 void UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::tokenize (GeneratorState& state, TokenStream& str) const
 {
 	str << Token(m_function.c_str()) << Token::LEFT_PAREN;
 	m_child->tokenize(state, str);
 	str << Token::RIGHT_PAREN;
 }

 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 void UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::evaluate (ExecutionContext& execCtx)
 {
 	m_child->evaluate(execCtx);

 	ExecConstValueAccess	srcValue	= m_child->getValue();
 	ExecValueAccess			dstValue	= m_value.getValue(m_inValueRange.getType());

 	for (int elemNdx = 0; elemNdx < m_inValueRange.getType().getNumElements(); elemNdx++)
 	{
 		ExecConstValueAccess	srcComp		= srcValue.component(elemNdx);
 		ExecValueAccess			dstComp		= dstValue.component(elemNdx);

 		for (int compNdx = 0; compNdx < EXEC_VEC_WIDTH; compNdx++)
 			dstComp.asFloat(compNdx) = Evaluate()(srcComp.asFloat(compNdx));
 	}
 }

 template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
 float UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange)
 {
 	// \todo [2011-06-14 pyry] Void support?
 	if (!valueRange.getType().isFloatOrVec())
 		return 0.0f;

 	int availableLevels = state.getShaderParameters().maxExpressionDepth - state.getExpressionDepth();

 	if (availableLevels < getConservativeValueExprDepth(state, valueRange) + 1)
 		return 0.0f;

 	// Compute value range weight
 	float combinedWeight = 1.0f;
 	for (int elemNdx = 0; elemNdx < valueRange.getType().getNumElements(); elemNdx++)
 	{
 		float elemWeight = GetValueRangeWeight()(valueRange.component(elemNdx).getMin().asFloat(), valueRange.component(elemNdx).getMax().asFloat());
 		combinedWeight *= elemWeight;
 	}

 	return combinedWeight;
 }

 // Proxy template.
 template <class C>
 struct GetUnaryBuiltinVecWeight
 {
 	inline float operator() (float outMin, float outMax) const { return C::getCompWeight(outMin, outMax); }
 };

 template <class C>
 struct ComputeUnaryBuiltinVecRange
 {
 	inline void operator() (float outMin, float outMax, float& inMin, float& inMax) const { C::computeValueRange(outMin, outMax, inMin, inMax); }
 };

 template <class C>
 struct EvaluateUnaryBuiltinVec
 {
 	inline float operator() (float inVal) const { return C::evaluateComp(inVal); }
 };

 template <class C>
 class UnaryBuiltinVecTemplateProxy : public UnaryBuiltinVecFunc<GetUnaryBuiltinVecWeight<C>, ComputeUnaryBuiltinVecRange<C>, EvaluateUnaryBuiltinVec<C> >
 {
 public:
 	UnaryBuiltinVecTemplateProxy (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
 		: UnaryBuiltinVecFunc<GetUnaryBuiltinVecWeight<C>, ComputeUnaryBuiltinVecRange<C>, EvaluateUnaryBuiltinVec<C> >(state, function, valueRange)
 	{
 	}
 };

 // Template for trigonometric function group.
 template <class C>
 class UnaryTrigonometricFunc : public UnaryBuiltinVecTemplateProxy<C>
 {
 public:
 	UnaryTrigonometricFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
 		: UnaryBuiltinVecTemplateProxy<C>(state, function, valueRange)
 	{
 	}

 	static inline float getCompWeight (float outMin, float outMax)
 	{
 		if (Scalar::min<float>() == outMin || Scalar::max<float>() == outMax)
 			return 1.0f; // Infinite value range, anything goes

 		// Transform range
 		float inMin, inMax;
 		if (!C::transformValueRange(outMin, outMax, inMin, inMax))
 			return 0.0f; // Not possible to transform value range (out of range perhaps)

 		// Quantize
 		if (!quantizeFloatRange(inMin, inMax))
 			return 0.0f; // Not possible to quantize - would cause accuracy issues

 		if (outMin == outMax)
 			return 1.0f; // Constant value and passed quantization

 		// Evaluate new intersection
 		float intersectionLen	= C::evaluateComp(inMax) - C::evaluateComp(inMin);
 		float valRangeLen		= outMax - outMin;

 		return deFloatMax(0.1f, intersectionLen/valRangeLen);
 	}

 	static inline void computeValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		DE_VERIFY(C::transformValueRange(outMin, outMax, inMin, inMax));
 		DE_VERIFY(quantizeFloatRange(inMin, inMax));
 		DE_ASSERT(inMin <= inMax);
 	}

 	static float getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange)
 	{
 		if (state.getProgramParameters().trigonometricBaseWeight <= 0.0f)
 			return 0.0f;

 		return UnaryBuiltinVecTemplateProxy<C>::getWeight(state, valueRange) * state.getProgramParameters().trigonometricBaseWeight;
 	}
 };

 class SinOp : public UnaryTrigonometricFunc<SinOp>
 {
 public:
 	SinOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryTrigonometricFunc<SinOp>(state, "sin", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		if (outMax < -1.0f || outMin > 1.0f)
 			return false;

 		inMin = (outMin >= -1.0f) ? deFloatAsin(outMin) : -0.5f*DE_PI;
 		inMax = (outMax <= +1.0f) ? deFloatAsin(outMax) : +0.5f*DE_PI;

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatSin(inVal);
 	}
 };

 class CosOp : public UnaryTrigonometricFunc<CosOp>
 {
 public:
 	CosOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryTrigonometricFunc<CosOp>(state, "cos", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		if (outMax < -1.0f || outMin > 1.0f)
 			return false;

 		inMax = (outMin >= -1.0f) ? deFloatAcos(outMin) : +DE_PI;
 		inMin = (outMax <= +1.0f) ? deFloatAcos(outMax) : -DE_PI;

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatCos(inVal);
 	}
 };

 class TanOp : public UnaryTrigonometricFunc<TanOp>
 {
 public:
 	TanOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryTrigonometricFunc<TanOp>(state, "tan", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// \note Currently tan() is limited to -4..4 range. Otherwise we will run into accuracy issues
 		const float rangeMin = -4.0f;
 		const float rangeMax = +4.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false;

 		inMin = deFloatAtanOver(deFloatMax(outMin, rangeMin));
 		inMax = deFloatAtanOver(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatTan(inVal);
 	}
 };

 class AsinOp : public UnaryTrigonometricFunc<AsinOp>
 {
 public:
 	AsinOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryTrigonometricFunc<AsinOp>(state, "asin", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		const float rangeMin = -DE_PI/2.0f;
 		const float rangeMax = +DE_PI/2.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatSin(deFloatMax(outMin, rangeMin));
 		inMax = deFloatSin(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatAsin(inVal);
 	}
 };

 class AcosOp : public UnaryTrigonometricFunc<AcosOp>
 {
 public:
 	AcosOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryTrigonometricFunc<AcosOp>(state, "acos", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		const float rangeMin = 0.0f;
 		const float rangeMax = DE_PI;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMax = deFloatCos(deFloatMax(outMin, rangeMin));
 		inMin = deFloatCos(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatAcos(inVal);
 	}
 };

 class AtanOp : public UnaryTrigonometricFunc<AtanOp>
 {
 public:
 	AtanOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryTrigonometricFunc<AtanOp>(state, "atan", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// \note For accuracy reasons output range is limited to -1..1
 		const float rangeMin = -1.0f;
 		const float rangeMax = +1.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatTan(deFloatMax(outMin, rangeMin));
 		inMax = deFloatTan(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatAtanOver(inVal);
 	}
 };

 // Template for exponential function group.
 // \todo [2011-07-07 pyry] Shares most of the code with Trigonometric variant..
 template <class C>
 class UnaryExponentialFunc : public UnaryBuiltinVecTemplateProxy<C>
 {
 public:
 	UnaryExponentialFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
 		: UnaryBuiltinVecTemplateProxy<C>(state, function, valueRange)
 	{
 	}

 	static inline float getCompWeight (float outMin, float outMax)
 	{
 		if (Scalar::min<float>() == outMin || Scalar::max<float>() == outMax)
 			return 1.0f; // Infinite value range, anything goes

 		// Transform range
 		float inMin, inMax;
 		if (!C::transformValueRange(outMin, outMax, inMin, inMax))
 			return 0.0f; // Not possible to transform value range (out of range perhaps)

 		// Quantize
 		if (!quantizeFloatRange(inMin, inMax))
 			return 0.0f; // Not possible to quantize - would cause accuracy issues

 		if (outMin == outMax)
 			return 1.0f; // Constant value and passed quantization

 		// Evaluate new intersection
 		float intersectionLen	= C::evaluateComp(inMax) - C::evaluateComp(inMin);
 		float valRangeLen		= outMax - outMin;

 		return deFloatMax(0.1f, intersectionLen/valRangeLen);
 	}

 	static inline void computeValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		DE_VERIFY(C::transformValueRange(outMin, outMax, inMin, inMax));
 		DE_VERIFY(quantizeFloatRange(inMin, inMax));
 		DE_ASSERT(inMin <= inMax);
 	}

 	static float getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange)
 	{
 		if (state.getProgramParameters().exponentialBaseWeight <= 0.0f)
 			return 0.0f;

 		return UnaryBuiltinVecTemplateProxy<C>::getWeight(state, valueRange) * state.getProgramParameters().exponentialBaseWeight;
 	}
 };

 class ExpOp : public UnaryExponentialFunc<ExpOp>
 {
 public:
 	ExpOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryExponentialFunc<ExpOp>(state, "exp", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// Limited due to accuracy reasons, should be 0..+inf
 		const float rangeMin = 0.1f;
 		const float rangeMax = 10.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatLog(deFloatMax(outMin, rangeMin));
 		inMax = deFloatLog(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatExp(inVal);
 	}
 };

 class LogOp : public UnaryExponentialFunc<LogOp>
 {
 public:
 	LogOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryExponentialFunc<LogOp>(state, "log", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// Limited due to accuracy reasons, should be -inf..+inf
 		const float rangeMin = 0.1f;
 		const float rangeMax = 6.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatExp(deFloatMax(outMin, rangeMin));
 		inMax = deFloatExp(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatLog(inVal);
 	}
 };

 class Exp2Op : public UnaryExponentialFunc<Exp2Op>
 {
 public:
 	Exp2Op (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryExponentialFunc<Exp2Op>(state, "exp2", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// Limited due to accuracy reasons, should be 0..+inf
 		const float rangeMin = 0.1f;
 		const float rangeMax = 10.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatLog2(deFloatMax(outMin, rangeMin));
 		inMax = deFloatLog2(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatExp2(inVal);
 	}
 };

 class Log2Op : public UnaryExponentialFunc<Log2Op>
 {
 public:
 	Log2Op (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryExponentialFunc<Log2Op>(state, "log2", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// Limited due to accuracy reasons, should be -inf..+inf
 		const float rangeMin = 0.1f;
 		const float rangeMax = 6.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatExp2(deFloatMax(outMin, rangeMin));
 		inMax = deFloatExp2(deFloatMin(outMax, rangeMax));

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatLog2(inVal);
 	}
 };

 class SqrtOp : public UnaryExponentialFunc<SqrtOp>
 {
 public:
 	SqrtOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryExponentialFunc<SqrtOp>(state, "sqrt", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// Limited due to accuracy reasons, should be 0..+inf
 		const float rangeMin = 0.0f;
 		const float rangeMax = 4.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMin = deFloatMax(outMin, rangeMin);
 		inMax = deFloatMin(outMax, rangeMax);

 		inMin *= inMin;
 		inMax *= inMax;

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return deFloatSqrt(inVal);
 	}
 };

 class InvSqrtOp : public UnaryExponentialFunc<InvSqrtOp>
 {
 public:
 	InvSqrtOp (GeneratorState& state, ConstValueRangeAccess valueRange)
 		: UnaryExponentialFunc<InvSqrtOp>(state, "inversesqrt", valueRange)
 	{
 	}

 	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
 	{
 		// Limited due to accuracy reasons
 		const float rangeMin = 0.4f;
 		const float rangeMax = 3.0f;

 		if (outMax < rangeMin || outMin > rangeMax)
 			return false; // Out of range

 		inMax = 1.0f/deFloatMax(outMin, rangeMin);
 		inMin = 1.0f/deFloatMin(outMax, rangeMax);

 		inMin *= inMin;
 		inMax *= inMax;

 		return true;
 	}

 	static inline float evaluateComp (float inVal)
 	{
 		return 1.0f/deFloatSqrt(inVal);
 	}
 };

 } // rsg

 #endif // _RSGBUILTINFUNCTIONS_HPP
	#ifndef _RSGBUILTINFUNCTIONS_HPP
	#define _RSGBUILTINFUNCTIONS_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 Built-in Functions.
	//--------------------------------------------------------------------*/

	#include "rsgDefs.hpp"
	#include "rsgExpression.hpp"
	#include "rsgUtils.hpp"
	#include "deMath.h"

	namespace rsg
	{

	// Template for built-in functions with form "GenType func(GenType val)".
	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	class UnaryBuiltinVecFunc : public Expression
	{
	public:
	UnaryBuiltinVecFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange);
	virtual ~UnaryBuiltinVecFunc (void);

	Expression* createNextChild (GeneratorState& state);
	void tokenize (GeneratorState& state, TokenStream& str) const;

	void evaluate (ExecutionContext& execCtx);
	ExecConstValueAccess getValue (void) const { return m_value.getValue(m_inValueRange.getType()); }

	static float getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange);

	private:
	std::string m_function;
	ValueRange m_inValueRange;
	ExecValueStorage m_value;
	Expression* m_child;
	};

	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::UnaryBuiltinVecFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
	: m_function (function)
	, m_inValueRange (valueRange.getType())
	, m_child (DE_NULL)
	{
	DE_UNREF(state);
	DE_ASSERT(valueRange.getType().isFloatOrVec());

	m_value.setStorage(valueRange.getType());

	// Compute input value range
	for (int ndx = 0; ndx < m_inValueRange.getType().getNumElements(); ndx++)
	{
	ConstValueRangeAccess outRange = valueRange.component(ndx);
	ValueRangeAccess inRange = m_inValueRange.asAccess().component(ndx);

	ComputeValueRange()(outRange.getMin().asFloat(), outRange.getMax().asFloat(), inRange.getMin().asFloat(), inRange.getMax().asFloat());
	}
	}

	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::~UnaryBuiltinVecFunc (void)
	{
	delete m_child;
	}

	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	Expression* UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::createNextChild (GeneratorState& state)
	{
	if (m_child)
	return DE_NULL;

	m_child = Expression::createRandom(state, m_inValueRange.asAccess());
	return m_child;
	}

	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	void UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::tokenize (GeneratorState& state, TokenStream& str) const
	{
	str << Token(m_function.c_str()) << Token::LEFT_PAREN;
	m_child->tokenize(state, str);
	str << Token::RIGHT_PAREN;
	}

	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	void UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::evaluate (ExecutionContext& execCtx)
	{
	m_child->evaluate(execCtx);

	ExecConstValueAccess srcValue = m_child->getValue();
	ExecValueAccess dstValue = m_value.getValue(m_inValueRange.getType());

	for (int elemNdx = 0; elemNdx < m_inValueRange.getType().getNumElements(); elemNdx++)
	{
	ExecConstValueAccess srcComp = srcValue.component(elemNdx);
	ExecValueAccess dstComp = dstValue.component(elemNdx);

	for (int compNdx = 0; compNdx < EXEC_VEC_WIDTH; compNdx++)
	dstComp.asFloat(compNdx) = Evaluate()(srcComp.asFloat(compNdx));
	}
	}

	template <class GetValueRangeWeight, class ComputeValueRange, class Evaluate>
	float UnaryBuiltinVecFunc<GetValueRangeWeight, ComputeValueRange, Evaluate>::getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange)
	{
	// \todo [2011-06-14 pyry] Void support?
	if (!valueRange.getType().isFloatOrVec())
	return 0.0f;

	int availableLevels = state.getShaderParameters().maxExpressionDepth - state.getExpressionDepth();

	if (availableLevels < getConservativeValueExprDepth(state, valueRange) + 1)
	return 0.0f;

	// Compute value range weight
	float combinedWeight = 1.0f;
	for (int elemNdx = 0; elemNdx < valueRange.getType().getNumElements(); elemNdx++)
	{
	float elemWeight = GetValueRangeWeight()(valueRange.component(elemNdx).getMin().asFloat(), valueRange.component(elemNdx).getMax().asFloat());
	combinedWeight *= elemWeight;
	}

	return combinedWeight;
	}

	// Proxy template.
	template <class C>
	struct GetUnaryBuiltinVecWeight
	{
	inline float operator() (float outMin, float outMax) const { return C::getCompWeight(outMin, outMax); }
	};

	template <class C>
	struct ComputeUnaryBuiltinVecRange
	{
	inline void operator() (float outMin, float outMax, float& inMin, float& inMax) const { C::computeValueRange(outMin, outMax, inMin, inMax); }
	};

	template <class C>
	struct EvaluateUnaryBuiltinVec
	{
	inline float operator() (float inVal) const { return C::evaluateComp(inVal); }
	};

	template <class C>
	class UnaryBuiltinVecTemplateProxy : public UnaryBuiltinVecFunc<GetUnaryBuiltinVecWeight<C>, ComputeUnaryBuiltinVecRange<C>, EvaluateUnaryBuiltinVec<C> >
	{
	public:
	UnaryBuiltinVecTemplateProxy (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
	: UnaryBuiltinVecFunc<GetUnaryBuiltinVecWeight<C>, ComputeUnaryBuiltinVecRange<C>, EvaluateUnaryBuiltinVec<C> >(state, function, valueRange)
	{
	}
	};

	// Template for trigonometric function group.
	template <class C>
	class UnaryTrigonometricFunc : public UnaryBuiltinVecTemplateProxy<C>
	{
	public:
	UnaryTrigonometricFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
	: UnaryBuiltinVecTemplateProxy<C>(state, function, valueRange)
	{
	}

	static inline float getCompWeight (float outMin, float outMax)
	{
	if (Scalar::min<float>() == outMin \|\| Scalar::max<float>() == outMax)
	return 1.0f; // Infinite value range, anything goes

	// Transform range
	float inMin, inMax;
	if (!C::transformValueRange(outMin, outMax, inMin, inMax))
	return 0.0f; // Not possible to transform value range (out of range perhaps)

	// Quantize
	if (!quantizeFloatRange(inMin, inMax))
	return 0.0f; // Not possible to quantize - would cause accuracy issues

	if (outMin == outMax)
	return 1.0f; // Constant value and passed quantization

	// Evaluate new intersection
	float intersectionLen = C::evaluateComp(inMax) - C::evaluateComp(inMin);
	float valRangeLen = outMax - outMin;

	return deFloatMax(0.1f, intersectionLen/valRangeLen);
	}

	static inline void computeValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	DE_VERIFY(C::transformValueRange(outMin, outMax, inMin, inMax));
	DE_VERIFY(quantizeFloatRange(inMin, inMax));
	DE_ASSERT(inMin <= inMax);
	}

	static float getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange)
	{
	if (state.getProgramParameters().trigonometricBaseWeight <= 0.0f)
	return 0.0f;

	return UnaryBuiltinVecTemplateProxy<C>::getWeight(state, valueRange) * state.getProgramParameters().trigonometricBaseWeight;
	}
	};

	class SinOp : public UnaryTrigonometricFunc<SinOp>
	{
	public:
	SinOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryTrigonometricFunc<SinOp>(state, "sin", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	if (outMax < -1.0f \|\| outMin > 1.0f)
	return false;

	inMin = (outMin >= -1.0f) ? deFloatAsin(outMin) : -0.5f*DE_PI;
	inMax = (outMax <= +1.0f) ? deFloatAsin(outMax) : +0.5f*DE_PI;

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatSin(inVal);
	}
	};

	class CosOp : public UnaryTrigonometricFunc<CosOp>
	{
	public:
	CosOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryTrigonometricFunc<CosOp>(state, "cos", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	if (outMax < -1.0f \|\| outMin > 1.0f)
	return false;

	inMax = (outMin >= -1.0f) ? deFloatAcos(outMin) : +DE_PI;
	inMin = (outMax <= +1.0f) ? deFloatAcos(outMax) : -DE_PI;

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatCos(inVal);
	}
	};

	class TanOp : public UnaryTrigonometricFunc<TanOp>
	{
	public:
	TanOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryTrigonometricFunc<TanOp>(state, "tan", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// \note Currently tan() is limited to -4..4 range. Otherwise we will run into accuracy issues
	const float rangeMin = -4.0f;
	const float rangeMax = +4.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false;

	inMin = deFloatAtanOver(deFloatMax(outMin, rangeMin));
	inMax = deFloatAtanOver(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatTan(inVal);
	}
	};

	class AsinOp : public UnaryTrigonometricFunc<AsinOp>
	{
	public:
	AsinOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryTrigonometricFunc<AsinOp>(state, "asin", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	const float rangeMin = -DE_PI/2.0f;
	const float rangeMax = +DE_PI/2.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatSin(deFloatMax(outMin, rangeMin));
	inMax = deFloatSin(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatAsin(inVal);
	}
	};

	class AcosOp : public UnaryTrigonometricFunc<AcosOp>
	{
	public:
	AcosOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryTrigonometricFunc<AcosOp>(state, "acos", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	const float rangeMin = 0.0f;
	const float rangeMax = DE_PI;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMax = deFloatCos(deFloatMax(outMin, rangeMin));
	inMin = deFloatCos(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatAcos(inVal);
	}
	};

	class AtanOp : public UnaryTrigonometricFunc<AtanOp>
	{
	public:
	AtanOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryTrigonometricFunc<AtanOp>(state, "atan", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// \note For accuracy reasons output range is limited to -1..1
	const float rangeMin = -1.0f;
	const float rangeMax = +1.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatTan(deFloatMax(outMin, rangeMin));
	inMax = deFloatTan(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatAtanOver(inVal);
	}
	};

	// Template for exponential function group.
	// \todo [2011-07-07 pyry] Shares most of the code with Trigonometric variant..
	template <class C>
	class UnaryExponentialFunc : public UnaryBuiltinVecTemplateProxy<C>
	{
	public:
	UnaryExponentialFunc (GeneratorState& state, const char* function, ConstValueRangeAccess valueRange)
	: UnaryBuiltinVecTemplateProxy<C>(state, function, valueRange)
	{
	}

	static inline float getCompWeight (float outMin, float outMax)
	{
	if (Scalar::min<float>() == outMin \|\| Scalar::max<float>() == outMax)
	return 1.0f; // Infinite value range, anything goes

	// Transform range
	float inMin, inMax;
	if (!C::transformValueRange(outMin, outMax, inMin, inMax))
	return 0.0f; // Not possible to transform value range (out of range perhaps)

	// Quantize
	if (!quantizeFloatRange(inMin, inMax))
	return 0.0f; // Not possible to quantize - would cause accuracy issues

	if (outMin == outMax)
	return 1.0f; // Constant value and passed quantization

	// Evaluate new intersection
	float intersectionLen = C::evaluateComp(inMax) - C::evaluateComp(inMin);
	float valRangeLen = outMax - outMin;

	return deFloatMax(0.1f, intersectionLen/valRangeLen);
	}

	static inline void computeValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	DE_VERIFY(C::transformValueRange(outMin, outMax, inMin, inMax));
	DE_VERIFY(quantizeFloatRange(inMin, inMax));
	DE_ASSERT(inMin <= inMax);
	}

	static float getWeight (const GeneratorState& state, ConstValueRangeAccess valueRange)
	{
	if (state.getProgramParameters().exponentialBaseWeight <= 0.0f)
	return 0.0f;

	return UnaryBuiltinVecTemplateProxy<C>::getWeight(state, valueRange) * state.getProgramParameters().exponentialBaseWeight;
	}
	};

	class ExpOp : public UnaryExponentialFunc<ExpOp>
	{
	public:
	ExpOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryExponentialFunc<ExpOp>(state, "exp", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// Limited due to accuracy reasons, should be 0..+inf
	const float rangeMin = 0.1f;
	const float rangeMax = 10.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatLog(deFloatMax(outMin, rangeMin));
	inMax = deFloatLog(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatExp(inVal);
	}
	};

	class LogOp : public UnaryExponentialFunc<LogOp>
	{
	public:
	LogOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryExponentialFunc<LogOp>(state, "log", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// Limited due to accuracy reasons, should be -inf..+inf
	const float rangeMin = 0.1f;
	const float rangeMax = 6.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatExp(deFloatMax(outMin, rangeMin));
	inMax = deFloatExp(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatLog(inVal);
	}
	};

	class Exp2Op : public UnaryExponentialFunc<Exp2Op>
	{
	public:
	Exp2Op (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryExponentialFunc<Exp2Op>(state, "exp2", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// Limited due to accuracy reasons, should be 0..+inf
	const float rangeMin = 0.1f;
	const float rangeMax = 10.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatLog2(deFloatMax(outMin, rangeMin));
	inMax = deFloatLog2(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatExp2(inVal);
	}
	};

	class Log2Op : public UnaryExponentialFunc<Log2Op>
	{
	public:
	Log2Op (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryExponentialFunc<Log2Op>(state, "log2", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// Limited due to accuracy reasons, should be -inf..+inf
	const float rangeMin = 0.1f;
	const float rangeMax = 6.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatExp2(deFloatMax(outMin, rangeMin));
	inMax = deFloatExp2(deFloatMin(outMax, rangeMax));

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatLog2(inVal);
	}
	};

	class SqrtOp : public UnaryExponentialFunc<SqrtOp>
	{
	public:
	SqrtOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryExponentialFunc<SqrtOp>(state, "sqrt", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// Limited due to accuracy reasons, should be 0..+inf
	const float rangeMin = 0.0f;
	const float rangeMax = 4.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMin = deFloatMax(outMin, rangeMin);
	inMax = deFloatMin(outMax, rangeMax);

	inMin *= inMin;
	inMax *= inMax;

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return deFloatSqrt(inVal);
	}
	};

	class InvSqrtOp : public UnaryExponentialFunc<InvSqrtOp>
	{
	public:
	InvSqrtOp (GeneratorState& state, ConstValueRangeAccess valueRange)
	: UnaryExponentialFunc<InvSqrtOp>(state, "inversesqrt", valueRange)
	{
	}

	static inline bool transformValueRange (float outMin, float outMax, float& inMin, float& inMax)
	{
	// Limited due to accuracy reasons
	const float rangeMin = 0.4f;
	const float rangeMax = 3.0f;

	if (outMax < rangeMin \|\| outMin > rangeMax)
	return false; // Out of range

	inMax = 1.0f/deFloatMax(outMin, rangeMin);
	inMin = 1.0f/deFloatMin(outMax, rangeMax);

	inMin *= inMin;
	inMax *= inMax;

	return true;
	}

	static inline float evaluateComp (float inVal)
	{
	return 1.0f/deFloatSqrt(inVal);
	}
	};

	} // rsg

	#endif // _RSGBUILTINFUNCTIONS_HPP