source-engine/mathlib/lightdesc.cpp

//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: 
//
//=====================================================================================//

#include <ssemath.h>
#include <lightdesc.h>
#include "mathlib.h"

void LightDesc_t::RecalculateDerivedValues(void)
{
	m_Flags = LIGHTTYPE_OPTIMIZATIONFLAGS_DERIVED_VALUES_CALCED;
	if (m_Attenuation0)
		m_Flags|=LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION0;
	if (m_Attenuation1)
		m_Flags|=LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION1;
	if (m_Attenuation2)
		m_Flags|=LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION2;
	
	if (m_Type==MATERIAL_LIGHT_SPOT)
	{
		m_ThetaDot=cos(m_Theta);
		m_PhiDot=cos(m_Phi);
		float spread=m_ThetaDot-m_PhiDot;
		if (spread>1.0e-10)
		{
			// note - this quantity is very sensitive to round off error. the sse
			// reciprocal approximation won't cut it here.
			OneOver_ThetaDot_Minus_PhiDot=1.0/spread;
		}
		else
		{
			// hard falloff instead of divide by zero
			OneOver_ThetaDot_Minus_PhiDot=1.0;
		}				
	}	
	if (m_Type==MATERIAL_LIGHT_DIRECTIONAL)
	{
		// set position to be real far away in the right direction
		m_Position=m_Direction;
		m_Position *= 2.0e6;
	}
	
	m_RangeSquared=m_Range*m_Range;

}

void LightDesc_t::ComputeLightAtPointsForDirectional(
	const FourVectors &pos, const FourVectors &normal,
	FourVectors &color, bool DoHalfLambert ) const
{
	FourVectors delta;
	delta.DuplicateVector(m_Direction);
//	delta.VectorNormalizeFast();
	fltx4 strength=delta*normal;
	if (DoHalfLambert)
	{
		strength=AddSIMD(MulSIMD(strength,Four_PointFives),Four_PointFives);
	}
	else
		strength=MaxSIMD(Four_Zeros,delta*normal);
		
	color.x=AddSIMD(color.x,MulSIMD(strength,ReplicateX4(m_Color.x)));
	color.y=AddSIMD(color.y,MulSIMD(strength,ReplicateX4(m_Color.y)));
	color.z=AddSIMD(color.z,MulSIMD(strength,ReplicateX4(m_Color.z)));
}


void LightDesc_t::ComputeLightAtPoints( const FourVectors &pos, const FourVectors &normal,
										FourVectors &color, bool DoHalfLambert ) const
{
	FourVectors delta;
	Assert((m_Type==MATERIAL_LIGHT_POINT) || (m_Type==MATERIAL_LIGHT_SPOT) || (m_Type==MATERIAL_LIGHT_DIRECTIONAL));
	switch (m_Type)
	{
		case MATERIAL_LIGHT_POINT:
		case MATERIAL_LIGHT_SPOT:
			delta.DuplicateVector(m_Position);
			delta-=pos;
			break;
				
		case MATERIAL_LIGHT_DIRECTIONAL:
			ComputeLightAtPointsForDirectional( pos, normal, color, DoHalfLambert );
			return;
	}

	fltx4 dist2 = delta*delta;

	dist2=MaxSIMD( Four_Ones, dist2 );

	fltx4 falloff;

	if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION0 )
	{
		falloff = ReplicateX4(m_Attenuation0);
	}
	else
		falloff= Four_Epsilons;

	if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION1 )
	{
		falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation1),SqrtEstSIMD(dist2)));
	}

	if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION2 )
	{
		falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation2),dist2));
	}

	falloff=ReciprocalEstSIMD(falloff);
	// Cull out light beyond this radius
	// now, zero out elements for which dist2 was > range^2. !!speed!! lights should store dist^2 in sse format
	if (m_Range != 0.f)
	{
		fltx4 RangeSquared=ReplicateX4(m_RangeSquared); // !!speed!!
		falloff=AndSIMD(falloff,CmpLtSIMD(dist2,RangeSquared));
	}

	delta.VectorNormalizeFast();
	fltx4 strength=delta*normal;
	if (DoHalfLambert)
	{
		strength=AddSIMD(MulSIMD(strength,Four_PointFives),Four_PointFives);
	}
	else
		strength=MaxSIMD(Four_Zeros,delta*normal);
		
	switch(m_Type)
	{
		case MATERIAL_LIGHT_POINT:
			// half-lambert
			break;
				
		case MATERIAL_LIGHT_SPOT:
		{
			fltx4 dot2=SubSIMD(Four_Zeros,delta*m_Direction); // dot position with spot light dir for cone falloff


			fltx4 cone_falloff_scale=MulSIMD(ReplicateX4(OneOver_ThetaDot_Minus_PhiDot),
												 SubSIMD(dot2,ReplicateX4(m_PhiDot)));
			cone_falloff_scale=MinSIMD(cone_falloff_scale,Four_Ones);
			
			if ((m_Falloff!=0.0) && (m_Falloff!=1.0))
			{
				// !!speed!! could compute integer exponent needed by powsimd and store in light
				cone_falloff_scale=PowSIMD(cone_falloff_scale,m_Falloff);
			}
			strength=MulSIMD(cone_falloff_scale,strength);

			// now, zero out lighting where dot2<phidot. This will mask out any invalid results
			// from pow function, etc
			fltx4 OutsideMask=CmpGtSIMD(dot2,ReplicateX4(m_PhiDot)); // outside light cone?
			strength=AndSIMD(OutsideMask,strength);
		}
		break;
			

	}
	strength=MulSIMD(strength,falloff);
	color.x=AddSIMD(color.x,MulSIMD(strength,ReplicateX4(m_Color.x)));
	color.y=AddSIMD(color.y,MulSIMD(strength,ReplicateX4(m_Color.y)));
	color.z=AddSIMD(color.z,MulSIMD(strength,ReplicateX4(m_Color.z)));
}


void LightDesc_t::ComputeNonincidenceLightAtPoints( const FourVectors &pos, FourVectors &color ) const
{
	FourVectors delta;
	Assert((m_Type==MATERIAL_LIGHT_POINT) || (m_Type==MATERIAL_LIGHT_SPOT) || (m_Type==MATERIAL_LIGHT_DIRECTIONAL));
	switch (m_Type)
	{
		case MATERIAL_LIGHT_POINT:
		case MATERIAL_LIGHT_SPOT:
			delta.DuplicateVector(m_Position);
			delta-=pos;
			break;
				
		case MATERIAL_LIGHT_DIRECTIONAL:
			return;
	}

	fltx4 dist2 = delta*delta;

	dist2=MaxSIMD( Four_Ones, dist2 );

	fltx4 falloff;

	if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION0 )
	{
		falloff = ReplicateX4(m_Attenuation0);
	}
	else
		falloff= Four_Epsilons;

	if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION1 )
	{
		falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation1),SqrtEstSIMD(dist2)));
	}

	if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION2 )
	{
		falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation2),dist2));
	}

	falloff=ReciprocalEstSIMD(falloff);
	// Cull out light beyond this radius
	// now, zero out elements for which dist2 was > range^2. !!speed!! lights should store dist^2 in sse format
	if (m_Range != 0.f)
	{
		fltx4 RangeSquared=ReplicateX4(m_RangeSquared); // !!speed!!
		falloff=AndSIMD(falloff,CmpLtSIMD(dist2,RangeSquared));
	}

	delta.VectorNormalizeFast();
	fltx4 strength = Four_Ones;
	//fltx4 strength=delta;
	//fltx4 strength = MaxSIMD(Four_Zeros,delta);
		
	switch(m_Type)
	{
		case MATERIAL_LIGHT_POINT:
			// half-lambert
			break;
				
		case MATERIAL_LIGHT_SPOT:
		{
			fltx4 dot2=SubSIMD(Four_Zeros,delta*m_Direction); // dot position with spot light dir for cone falloff


			fltx4 cone_falloff_scale=MulSIMD(ReplicateX4(OneOver_ThetaDot_Minus_PhiDot),
												 SubSIMD(dot2,ReplicateX4(m_PhiDot)));
			cone_falloff_scale=MinSIMD(cone_falloff_scale,Four_Ones);
			
			if ((m_Falloff!=0.0) && (m_Falloff!=1.0))
			{
				// !!speed!! could compute integer exponent needed by powsimd and store in light
				cone_falloff_scale=PowSIMD(cone_falloff_scale,m_Falloff);
			}
			strength=MulSIMD(cone_falloff_scale,strength);

			// now, zero out lighting where dot2<phidot. This will mask out any invalid results
			// from pow function, etc
			fltx4 OutsideMask=CmpGtSIMD(dot2,ReplicateX4(m_PhiDot)); // outside light cone?
			strength=AndSIMD(OutsideMask,strength);
		}
		break;
			

	}
	strength=MulSIMD(strength,falloff);
	color.x=AddSIMD(color.x,MulSIMD(strength,ReplicateX4(m_Color.x)));
	color.y=AddSIMD(color.y,MulSIMD(strength,ReplicateX4(m_Color.y)));
	color.z=AddSIMD(color.z,MulSIMD(strength,ReplicateX4(m_Color.z)));
}


void LightDesc_t::SetupOldStyleAttenuation( float fQuadraticAttn, float fLinearAttn, float fConstantAttn )
{
	// old-style manually typed quadrtiac coefficients
	if ( fQuadraticAttn < EQUAL_EPSILON )
		fQuadraticAttn = 0;
	
	if ( fLinearAttn < EQUAL_EPSILON)
		fLinearAttn = 0;
	
	if ( fConstantAttn < EQUAL_EPSILON)
		fConstantAttn = 0;
	
	if ( ( fConstantAttn < EQUAL_EPSILON ) && 
		 ( fLinearAttn < EQUAL_EPSILON ) && 
		 ( fQuadraticAttn < EQUAL_EPSILON ) )
		fConstantAttn = 1;

	m_Attenuation2=fQuadraticAttn;
	m_Attenuation1=fLinearAttn;
	m_Attenuation0=fConstantAttn;
	float fScaleFactor = fQuadraticAttn * 10000 + fLinearAttn * 100 + fConstantAttn;
	
	if ( fScaleFactor > 0 )
		m_Color *= fScaleFactor;
}

void LightDesc_t::SetupNewStyleAttenuation( float fFiftyPercentDistance, 
											float fZeroPercentDistance )
{
	// new style storing 50% and 0% distances
	float d50=fFiftyPercentDistance;
	float d0=fZeroPercentDistance;
	if (d0<d50)
	{
		// !!warning in lib code???!!!
		Warning("light has _fifty_percent_distance of %f but no zero_percent_distance\n",d50);
		d0=2.0*d50;
	}
	float a=0,b=1,c=0;
	if (! SolveInverseQuadraticMonotonic(0,1.0,d50,2.0,d0,256.0,a,b,c))
	{
		Warning("can't solve quadratic for light %f %f\n",d50,d0);
	}
	float v50=c+d50*(b+d50*a);
	float scale=2.0/v50;
	a*=scale;
	b*=scale;
	c*=scale;
	m_Attenuation2=a;
	m_Attenuation1=b;
	m_Attenuation0=c;
}
1 5 years ago			`//========= Copyright Valve Corporation, All rights reserved. ============//`
			`//`
			`// Purpose:`
			`//`
			`//=====================================================================================//`

			`#include <ssemath.h>`
			`#include <lightdesc.h>`
			`#include "mathlib.h"`

			`void LightDesc_t::RecalculateDerivedValues(void)`
			`{`
			`m_Flags = LIGHTTYPE_OPTIMIZATIONFLAGS_DERIVED_VALUES_CALCED;`
			`if (m_Attenuation0)`
			`m_Flags\|=LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION0;`
			`if (m_Attenuation1)`
			`m_Flags\|=LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION1;`
			`if (m_Attenuation2)`
			`m_Flags\|=LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION2;`

			`if (m_Type==MATERIAL_LIGHT_SPOT)`
			`{`
			`m_ThetaDot=cos(m_Theta);`
			`m_PhiDot=cos(m_Phi);`
			`float spread=m_ThetaDot-m_PhiDot;`
			`if (spread>1.0e-10)`
			`{`
			`// note - this quantity is very sensitive to round off error. the sse`
			`// reciprocal approximation won't cut it here.`
			`OneOver_ThetaDot_Minus_PhiDot=1.0/spread;`
			`}`
			`else`
			`{`
			`// hard falloff instead of divide by zero`
			`OneOver_ThetaDot_Minus_PhiDot=1.0;`
			`}`
			`}`
			`if (m_Type==MATERIAL_LIGHT_DIRECTIONAL)`
			`{`
			`// set position to be real far away in the right direction`
			`m_Position=m_Direction;`
			`m_Position *= 2.0e6;`
			`}`

			`m_RangeSquared=m_Range*m_Range;`

			`}`

			`void LightDesc_t::ComputeLightAtPointsForDirectional(`
			`const FourVectors &pos, const FourVectors &normal,`
			`FourVectors &color, bool DoHalfLambert ) const`
			`{`
			`FourVectors delta;`
			`delta.DuplicateVector(m_Direction);`
			`// delta.VectorNormalizeFast();`
			`fltx4 strength=delta*normal;`
			`if (DoHalfLambert)`
			`{`
			`strength=AddSIMD(MulSIMD(strength,Four_PointFives),Four_PointFives);`
			`}`
			`else`
			`strength=MaxSIMD(Four_Zeros,delta*normal);`

			`color.x=AddSIMD(color.x,MulSIMD(strength,ReplicateX4(m_Color.x)));`
			`color.y=AddSIMD(color.y,MulSIMD(strength,ReplicateX4(m_Color.y)));`
			`color.z=AddSIMD(color.z,MulSIMD(strength,ReplicateX4(m_Color.z)));`
			`}`


			`void LightDesc_t::ComputeLightAtPoints( const FourVectors &pos, const FourVectors &normal,`
			`FourVectors &color, bool DoHalfLambert ) const`
			`{`
			`FourVectors delta;`
			`Assert((m_Type==MATERIAL_LIGHT_POINT) \|\| (m_Type==MATERIAL_LIGHT_SPOT) \|\| (m_Type==MATERIAL_LIGHT_DIRECTIONAL));`
			`switch (m_Type)`
			`{`
			`case MATERIAL_LIGHT_POINT:`
			`case MATERIAL_LIGHT_SPOT:`
			`delta.DuplicateVector(m_Position);`
			`delta-=pos;`
			`break;`

			`case MATERIAL_LIGHT_DIRECTIONAL:`
			`ComputeLightAtPointsForDirectional( pos, normal, color, DoHalfLambert );`
			`return;`
			`}`

			`fltx4 dist2 = delta*delta;`

			`dist2=MaxSIMD( Four_Ones, dist2 );`

			`fltx4 falloff;`

			`if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION0 )`
			`{`
			`falloff = ReplicateX4(m_Attenuation0);`
			`}`
			`else`
			`falloff= Four_Epsilons;`

			`if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION1 )`
			`{`
			`falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation1),SqrtEstSIMD(dist2)));`
			`}`

			`if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION2 )`
			`{`
			`falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation2),dist2));`
			`}`

			`falloff=ReciprocalEstSIMD(falloff);`
			`// Cull out light beyond this radius`
			`// now, zero out elements for which dist2 was > range^2. !!speed!! lights should store dist^2 in sse format`
			`if (m_Range != 0.f)`
			`{`
			`fltx4 RangeSquared=ReplicateX4(m_RangeSquared); // !!speed!!`
			`falloff=AndSIMD(falloff,CmpLtSIMD(dist2,RangeSquared));`
			`}`

			`delta.VectorNormalizeFast();`
			`fltx4 strength=delta*normal;`
			`if (DoHalfLambert)`
			`{`
			`strength=AddSIMD(MulSIMD(strength,Four_PointFives),Four_PointFives);`
			`}`
			`else`
			`strength=MaxSIMD(Four_Zeros,delta*normal);`

			`switch(m_Type)`
			`{`
			`case MATERIAL_LIGHT_POINT:`
			`// half-lambert`
			`break;`

			`case MATERIAL_LIGHT_SPOT:`
			`{`
			`fltx4 dot2=SubSIMD(Four_Zeros,delta*m_Direction); // dot position with spot light dir for cone falloff`


			`fltx4 cone_falloff_scale=MulSIMD(ReplicateX4(OneOver_ThetaDot_Minus_PhiDot),`
			`SubSIMD(dot2,ReplicateX4(m_PhiDot)));`
			`cone_falloff_scale=MinSIMD(cone_falloff_scale,Four_Ones);`

			`if ((m_Falloff!=0.0) && (m_Falloff!=1.0))`
			`{`
			`// !!speed!! could compute integer exponent needed by powsimd and store in light`
			`cone_falloff_scale=PowSIMD(cone_falloff_scale,m_Falloff);`
			`}`
			`strength=MulSIMD(cone_falloff_scale,strength);`

			`// now, zero out lighting where dot2<phidot. This will mask out any invalid results`
			`// from pow function, etc`
			`fltx4 OutsideMask=CmpGtSIMD(dot2,ReplicateX4(m_PhiDot)); // outside light cone?`
			`strength=AndSIMD(OutsideMask,strength);`
			`}`
			`break;`


			`}`
			`strength=MulSIMD(strength,falloff);`
			`color.x=AddSIMD(color.x,MulSIMD(strength,ReplicateX4(m_Color.x)));`
			`color.y=AddSIMD(color.y,MulSIMD(strength,ReplicateX4(m_Color.y)));`
			`color.z=AddSIMD(color.z,MulSIMD(strength,ReplicateX4(m_Color.z)));`
			`}`



			`void LightDesc_t::ComputeNonincidenceLightAtPoints( const FourVectors &pos, FourVectors &color ) const`
			`{`
			`FourVectors delta;`
			`Assert((m_Type==MATERIAL_LIGHT_POINT) \|\| (m_Type==MATERIAL_LIGHT_SPOT) \|\| (m_Type==MATERIAL_LIGHT_DIRECTIONAL));`
			`switch (m_Type)`
			`{`
			`case MATERIAL_LIGHT_POINT:`
			`case MATERIAL_LIGHT_SPOT:`
			`delta.DuplicateVector(m_Position);`
			`delta-=pos;`
			`break;`

			`case MATERIAL_LIGHT_DIRECTIONAL:`
			`return;`
			`}`

			`fltx4 dist2 = delta*delta;`

			`dist2=MaxSIMD( Four_Ones, dist2 );`

			`fltx4 falloff;`

			`if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION0 )`
			`{`
			`falloff = ReplicateX4(m_Attenuation0);`
			`}`
			`else`
			`falloff= Four_Epsilons;`

			`if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION1 )`
			`{`
			`falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation1),SqrtEstSIMD(dist2)));`
			`}`

			`if( m_Flags & LIGHTTYPE_OPTIMIZATIONFLAGS_HAS_ATTENUATION2 )`
			`{`
			`falloff=AddSIMD(falloff,MulSIMD(ReplicateX4(m_Attenuation2),dist2));`
			`}`

			`falloff=ReciprocalEstSIMD(falloff);`
			`// Cull out light beyond this radius`
			`// now, zero out elements for which dist2 was > range^2. !!speed!! lights should store dist^2 in sse format`
			`if (m_Range != 0.f)`
			`{`
			`fltx4 RangeSquared=ReplicateX4(m_RangeSquared); // !!speed!!`
			`falloff=AndSIMD(falloff,CmpLtSIMD(dist2,RangeSquared));`
			`}`

			`delta.VectorNormalizeFast();`
			`fltx4 strength = Four_Ones;`
			`//fltx4 strength=delta;`
			`//fltx4 strength = MaxSIMD(Four_Zeros,delta);`

			`switch(m_Type)`
			`{`
			`case MATERIAL_LIGHT_POINT:`
			`// half-lambert`
			`break;`

			`case MATERIAL_LIGHT_SPOT:`
			`{`
			`fltx4 dot2=SubSIMD(Four_Zeros,delta*m_Direction); // dot position with spot light dir for cone falloff`


			`fltx4 cone_falloff_scale=MulSIMD(ReplicateX4(OneOver_ThetaDot_Minus_PhiDot),`
			`SubSIMD(dot2,ReplicateX4(m_PhiDot)));`
			`cone_falloff_scale=MinSIMD(cone_falloff_scale,Four_Ones);`

			`if ((m_Falloff!=0.0) && (m_Falloff!=1.0))`
			`{`
			`// !!speed!! could compute integer exponent needed by powsimd and store in light`
			`cone_falloff_scale=PowSIMD(cone_falloff_scale,m_Falloff);`
			`}`
			`strength=MulSIMD(cone_falloff_scale,strength);`

			`// now, zero out lighting where dot2<phidot. This will mask out any invalid results`
			`// from pow function, etc`
			`fltx4 OutsideMask=CmpGtSIMD(dot2,ReplicateX4(m_PhiDot)); // outside light cone?`
			`strength=AndSIMD(OutsideMask,strength);`
			`}`
			`break;`


			`}`
			`strength=MulSIMD(strength,falloff);`
			`color.x=AddSIMD(color.x,MulSIMD(strength,ReplicateX4(m_Color.x)));`
			`color.y=AddSIMD(color.y,MulSIMD(strength,ReplicateX4(m_Color.y)));`
			`color.z=AddSIMD(color.z,MulSIMD(strength,ReplicateX4(m_Color.z)));`
			`}`



			`void LightDesc_t::SetupOldStyleAttenuation( float fQuadraticAttn, float fLinearAttn, float fConstantAttn )`
			`{`
			`// old-style manually typed quadrtiac coefficients`
			`if ( fQuadraticAttn < EQUAL_EPSILON )`
			`fQuadraticAttn = 0;`

			`if ( fLinearAttn < EQUAL_EPSILON)`
			`fLinearAttn = 0;`

			`if ( fConstantAttn < EQUAL_EPSILON)`
			`fConstantAttn = 0;`

			`if ( ( fConstantAttn < EQUAL_EPSILON ) &&`
			`( fLinearAttn < EQUAL_EPSILON ) &&`
			`( fQuadraticAttn < EQUAL_EPSILON ) )`
			`fConstantAttn = 1;`

			`m_Attenuation2=fQuadraticAttn;`
			`m_Attenuation1=fLinearAttn;`
			`m_Attenuation0=fConstantAttn;`
			`float fScaleFactor = fQuadraticAttn * 10000 + fLinearAttn * 100 + fConstantAttn;`

			`if ( fScaleFactor > 0 )`
			`m_Color *= fScaleFactor;`
			`}`

			`void LightDesc_t::SetupNewStyleAttenuation( float fFiftyPercentDistance,`
			`float fZeroPercentDistance )`
			`{`
			`// new style storing 50% and 0% distances`
			`float d50=fFiftyPercentDistance;`
			`float d0=fZeroPercentDistance;`
			`if (d0<d50)`
			`{`
			`// !!warning in lib code???!!!`
			`Warning("light has _fifty_percent_distance of %f but no zero_percent_distance\n",d50);`
			`d0=2.0*d50;`
			`}`
			`float a=0,b=1,c=0;`
			`if (! SolveInverseQuadraticMonotonic(0,1.0,d50,2.0,d0,256.0,a,b,c))`
			`{`
			`Warning("can't solve quadratic for light %f %f\n",d50,d0);`
			`}`
			`float v50=c+d50(b+d50a);`
			`float scale=2.0/v50;`
			`a*=scale;`
			`b*=scale;`
			`c*=scale;`
			`m_Attenuation2=a;`
			`m_Attenuation1=b;`
			`m_Attenuation0=c;`
			`}`