shaders/old/deferred.shader

	#version 300 es

	precision highp float;
	
    in vec2 uv;
    in vec3 position;
	
	out vec2 v_uv;
	
    uniform mat4 viewProjection;

    
    void main(void) {
        v_uv = uv;
		
		gl_Position = viewProjection *  vec4(position, 1.0);
    }
	
	// #keplerEngine - Split 
	
	#version 300 es

	precision highp float;

	#define PI 3.14159265358979323846
	#define ANISOTROPY 0
	#define USE_IES_PROFILE 0
	#define TRANSPARENT_MATERIAL 0
	#define TRANSLUCENT_MATERIAL 0
	#define CUBEMAP_EDGE_FIXUP 0
	
	
	uniform float lightType;
	uniform vec3 lightGeometry;
	uniform samplerCube reflectionSampler;
	uniform float clearCoat;
	uniform vec3 clearCoatColor;
	uniform float clearCoatThickness;
	uniform float clearCoatRoughness;
	uniform vec3 lightDirection;	
	uniform float attenuation; 
	uniform float SourceRadius;
	uniform float SourceLength;
	uniform float environmentLuminance;
	uniform vec3 lightPosition;
	uniform vec3 lightColor;	
	uniform float lightIntensity;
	uniform float clearCoatIOR;
	uniform vec3 cameraPosition;
	
	
	uniform float metallic;
	
	
	#include "physically_based_shading.shader"
	
	
	#define TEXTURED_MATERIAL 1
	
	out vec4 fragmentColor;

	in vec2 v_uv;
	

	uniform float reflectance;
	

	uniform float anisotropy;
	
	
	uniform float roughness;


	uniform sampler2D diffuseSampler;
	uniform sampler2D normalSampler;
	uniform sampler2D tangentSampler;
	uniform sampler2D infoSampler;
	
	uniform sampler2D ambientOcclusionSampler;
	uniform sampler2D materialSampler;
	uniform sampler2D shadowNoiseSampler;
	uniform sampler2D shadowDepthSampler;
	
	
	uniform float luma_z;
	uniform float far;
	

	uniform mat4 InvProjection;
	uniform mat4 lightViewProjection;
	uniform vec2 screenSize;
	uniform float shadowBias;

	const float PackUpscale = 256. / 255.; // fraction -> 0..1 (including 1)
	const float UnpackDownscale = 255. / 256.; // 0..1 -> fraction (excluding 1)

	const vec3 PackFactors = vec3( 256. * 256. * 256., 256. * 256.,  256. );
	const vec4 UnpackFactors = UnpackDownscale / vec4( PackFactors, 1. );

	const float ShiftRight8 = 1. / 256.;

	vec4 packDepthToRGBA( const in float v ) {
		vec4 r = vec4( fract( v * PackFactors ), v );
		r.yzw -= r.xyz * ShiftRight8; // tidy overflow
		return r * PackUpscale;
	}

	float unpackRGBAToDepth( const in vec4 v ) {
		return dot( v, UnpackFactors );
	}
	
	
	float shadow_sample(sampler2D depthMap, vec2 coord)
	{
		return ( texture(depthMap, coord.xy).x );//DecodeFloatRGBA() ;
	}
	
	vec2 DoubleSampleRotated(sampler2D depthMap, vec4 p, vec4 rotMatr, vec4 kernel) {

		vec4 rotatedOff;

		rotatedOff = rotMatr.xyzw * kernel.xxww +
					 rotMatr.zwxy * kernel.yyzz;

		vec4 fetchPos = p.xyxy + rotatedOff;// + rotatedOff

		vec2 result;
		
		result.x = shadow_sample(depthMap, fetchPos.xy);
		result.y = shadow_sample(depthMap, fetchPos.zw);

		
		return result;
	}
	
	
	float PCF(sampler2D depthMap, vec4 p, vec2 randDirTC, float depth)
	{
	
		vec2 kernelRadius = vec2(4.0);
		
		vec4 irreg_kernel_2d[8];
		irreg_kernel_2d[0] = vec4(-0.556641,-0.037109,-0.654297, 0.111328); 
		irreg_kernel_2d[1] = vec4(0.173828,0.111328,0.064453, -0.359375); 
		irreg_kernel_2d[2] = vec4(0.001953,0.082031,-0.060547, 0.078125); 
		irreg_kernel_2d[3] = vec4(0.220703,-0.359375,-0.062500, 0.001953);
		irreg_kernel_2d[4] = vec4(0.242188,0.126953,-0.250000, -0.140625); 
		irreg_kernel_2d[5] = vec4(0.070313,-0.025391,0.148438, 0.082031); 
		irreg_kernel_2d[6] = vec4(-0.078125,0.013672,-0.314453, 0.013672);
		irreg_kernel_2d[7] = vec4(0.117188,-0.140625,-0.199219, 0.117188);

		vec2 vInvShadowMapWH = vec2(1.0 / 2048.0);
		
		const int kernelSize = 8;
		
		mediump float P_Z = depth; // p.z;

		vec4 p0 = vec4(p.xyz, 1.0);

		
		mediump vec2 rotScale = vec2(kernelRadius.y * 2.0);

		float shadowTest = 0.0;

		#define KERNEL_STEP_SIZE 2

			vec2 rotSample = 2.0 * texture(shadowDepthSampler, randDirTC.xy).xy - 1.0;
			rotSample.xy = normalize(rotSample.xy);
			rotSample.xy *= (kernelRadius.xy * vInvShadowMapWH.xy);

			vec4 rot = vec4(rotSample.x, -rotSample.y, rotSample.y, rotSample.x);

			const int kernelOffset = 0;

			for(int i=kernelOffset; i<kernelSize; i+=KERNEL_STEP_SIZE) // Loop over taps
			{

				mediump vec4 sampleDepth = vec4(0.0);
				vec4 irr =  irreg_kernel_2d[i+0];
				sampleDepth.xy = DoubleSampleRotated(depthMap, p0, rot, irr);
				sampleDepth.zw = DoubleSampleRotated(depthMap, p0, rot, irreg_kernel_2d[i+1]);
			
				mediump vec4 InShadow;
				InShadow.x = ( P_Z < sampleDepth.x + shadowBias ) ? 1. : 0.0;
				InShadow.y = ( P_Z < sampleDepth.y + shadowBias ) ? 1. : 0.0;
				InShadow.z = ( P_Z < sampleDepth.z + shadowBias  ) ? 1. : 0.0;
				InShadow.w = ( P_Z < sampleDepth.w + shadowBias  ) ? 1. : 0.0;

		
				const mediump float quality = 8.0; // 8 == high
				const mediump float fInvSamplNum = (1.0 / quality);
				
				shadowTest += dot(InShadow, vec4(fInvSamplNum));
			}

		return shadowTest;
	}

	float DecodeFloatRGBA( vec4 rgba ) {
		return (rgba).x;
	
	  //return dot( rgba, vec4(1.0, 1.0 / 255.0, 1.0 / 65025.0, 1.0 / 160581375.0) );
	}
	
	float poissonPCFmultitap(vec4 projCoords, float shadowDepth, vec2 uv)
	{
		const mediump float step = 1.0 - 1.0 / 8.0;
		const mediump float fScale = 0.025; // 0.025
		
		mediump float n = 0.0;
		
		mediump vec3 directions[8];
		float vSampleScale = 1.0 / 2048.0;
		
		
		directions[0] = normalize(vec3( 1.0, 1.0, 1.0))*fScale*(n+=step);
		directions[1] = normalize(vec3(-1.0,-1.0,-1.0))*fScale*(n+=step);
		directions[2] = normalize(vec3(-1.0,-1.0, 1.0))*fScale*(n+=step);
		directions[3] = normalize(vec3(-1.0, 1.0,-1.0))*fScale*(n+=step);
		directions[4] = normalize(vec3(-1.0, 1.0 ,1.0))*fScale*(n+=step);
		directions[5] = normalize(vec3( 1.0,-1.0,-1.0))*fScale*(n+=step);
		directions[6] = normalize(vec3( 1.0,-1.0, 1.0))*fScale*(n+=step);
		directions[7] = normalize(vec3( 1.0, 1.0,-1.0))*fScale*(n+=step);

		mediump vec3 randomSample = texture(shadowNoiseSampler, vec2(64.0, 64.0) * uv.xy / 4.0).xyz  * 2.0 - 1.0;
		
		
		float sum = 0.0;

		 for( int i = 0; i < 4; i++ ) {
		 	vec3 sampler = reflect(directions[0], randomSample) * vSampleScale;	
			
			float pixelDepth = DecodeFloatRGBA( texture(shadowDepthSampler, projCoords.xy+ sampler.xy ) ) ; // + sampler.xy     + sampler.z

			if( pixelDepth + shadowBias > shadowDepth) {
				sum += 1.0;
			} else {
				sum += 0.0;
			}
		 }

		return sum;
	}
		
	float linestep(float min, float max, float value) {  
		return clamp((value - min) / (max - min), 0., 1.);
	}

	float reduceBleeding(float p_max, float amount) {
		return linestep(amount, 1.0, p_max);
	}

	float ChebyshevUpperBound(vec2 moments, float distance) {  
		if (distance <= moments.x)
			return 1.0;
			
		float g_minVariance = .0007;

		float variance = moments.y - (moments.x*moments.x);
		variance = max(variance,g_minVariance);

		float d = distance - moments.x;
		float p_max = variance / (variance + d*d);

		return reduceBleeding(p_max, shadowBias);
	}
	
	float calculateShadowOcclusion( vec3 worldPosition, vec2 uv ) {

		vec4 projCoords = lightViewProjection *  vec4(worldPosition, 1.0) ;
		
		float shadowDepth = length( lightPosition - worldPosition ) / 99.0;

		projCoords.xy /= projCoords.w;
		projCoords = 0.51 * projCoords + 0.5;

		vec4 moments = texture( shadowDepthSampler, projCoords.xy );
		mediump vec2 randomSample = texture(shadowNoiseSampler, vec2(1024.) * uv / 64.0).xy  * 2.0 - 1.0;
			
		float outFrustum = 0.0;
	
		if(projCoords.x <  0.0 || projCoords.x > 1.0) {
			return 0.0;
		}
		
		if(projCoords.y <  0.0 || projCoords.y > 1.0) {
			return 0.0;
		}
		
		if(projCoords.z <  1.0) {
			return 0.0;
		}	
			
		return ChebyshevUpperBound(moments.xy, shadowDepth);
		return poissonPCFmultitap(projCoords, shadowDepth, uv);
		//return PCF( shadowDepthSampler, projCoords, randomSample, shadowDepth );


	}
	
	vec3 sampleReflection( vec3 r ) {
	
		return texture(reflectionSampler, r).xyz;
		
	}
	
	vec3 cubemapReflection( deferredMaterialData materialData ) {
	
		vec3 viewDir = ( cameraPosition - materialData.position );
		vec3 reflectionVector = reflect(-viewDir, normalize( materialData.normal ));
		vec3 reflectionSample = sampleReflection( reflectionVector );
		
		return reflectionSample;
	}
	
	
	const float gamma = 2.2;
	
	float toLinear(float v) {
	  return pow(v, gamma);
	}

	vec2 toLinear(vec2 v) {
	  return pow(v, vec2(gamma));
	}

	vec3 toLinear(vec3 v) {
	  return pow(v, vec3(gamma));
	}

	vec4 toLinear(vec4 v) {
	  return vec4(toLinear(v.rgb), v.a);
	}


	vec3 HDR_ACES(const vec3 x) {
		// Narkowicz 2015, "ACES Filmic Tone Mapping Curve"
		const float a = 2.51;
		const float b = 0.03;
		const float c = 2.43;
		const float d = 0.59;
		const float e = 0.14;
		return (x * (a * x + b)) / (x * (c * x + d) + e);
	}

	vec3 tonemap(const vec3 x) {
		return HDR_ACES(x);
	}

	float linearToSRGB(float c) {
		return (c <= 0.0031308) ? c * 12.92 : (pow(abs(c), 1.0 / 2.4) * 1.055) - 0.055;
	}

	vec3 linearToSRGB(vec3 c) {
		return vec3(linearToSRGB(c.r), linearToSRGB(c.g), linearToSRGB(c.b));
	}


	void main() {

		deferredMaterialData materialData;
		
		float gamma = 2.2;
	
		vec4 normalDepth 			= texture(normalSampler, 	v_uv);
		vec4 diffuseRoughness 		= texture(diffuseSampler, 	v_uv);
		vec4 positionMaterialIndex 	= texture(infoSampler, 		v_uv);
		vec4 depthNormal 			= texture(normalSampler, 	v_uv);
		vec4 shadowAmbientOcclusion = texture(ambientOcclusionSampler, v_uv);
		
		materialData.ambientOcclusion 	= shadowAmbientOcclusion.x;
		materialData.normal 			= normalize( depthNormal.xyz );
		materialData.baseColor 			= sRGBtoLinear(diffuseRoughness.rgb);
		materialData.position 			= positionMaterialIndex.xyz;
		materialData.index 				= positionMaterialIndex.w;
		materialData.roughness 			= diffuseRoughness.w;
		materialData.alpha 				= 1.0;
		materialData.shadowOcclusion 	= shadowAmbientOcclusion.y; //calculateShadowOcclusion( materialData.position, v_uv );
		materialData.metallic			= metallic;
		materialData.reflectance		= reflectance;
		//materialData.tangent			= tangent;

		//materialData.shadowOcclusion = 1.0;
		//materialData.baseColor = vec3(1.0);
		
		vec4 color = physically_based_shading( materialData );
			
		float exposure = 1.7;

		color.rgb *= exposure;

		vec3 finalRender = color.rgb;// + diffuse * .2
		
		
		// For fxaa
		float luma = sqrt( dot(color.rgb, vec3(0.299, 0.587, 0.114)) );
		
		if(luma_z == 1.0)
		
		//if(v_uv.x < 0.5)
			fragmentColor = vec4(linearToSRGB(tonemap(color.rgb)), luma);
		//else
		//	fragmentColor = vec4(vec3(materialData.ambientOcclusion), 1.0);
		
				//fragmentColor = vec4(linearToSRGB(tonemap(color.rgb)), 1.0);
		
		if(materialData.index == 100.0) {
		
			vec3 cubeReflectionSample = cubemapReflection( materialData );
			fragmentColor = vec4( cubeReflectionSample, 1.0 );
			
		}
		
	}
First commit 2025-11-17 17:18:43 +01:00			`#version 300 es`

			`precision highp float;`

			`in vec2 uv;`
			`in vec3 position;`

			`out vec2 v_uv;`

			`uniform mat4 viewProjection;`



			`void main(void) {`
			`v_uv = uv;`

			`gl_Position = viewProjection * vec4(position, 1.0);`
			`}`

			`// #keplerEngine - Split`

			`#version 300 es`

			`precision highp float;`

			`#define PI 3.14159265358979323846`
			`#define ANISOTROPY 0`
			`#define USE_IES_PROFILE 0`
			`#define TRANSPARENT_MATERIAL 0`
			`#define TRANSLUCENT_MATERIAL 0`
			`#define CUBEMAP_EDGE_FIXUP 0`


			`uniform float lightType;`
			`uniform vec3 lightGeometry;`
			`uniform samplerCube reflectionSampler;`
			`uniform float clearCoat;`
			`uniform vec3 clearCoatColor;`
			`uniform float clearCoatThickness;`
			`uniform float clearCoatRoughness;`
			`uniform vec3 lightDirection;`
			`uniform float attenuation;`
			`uniform float SourceRadius;`
			`uniform float SourceLength;`
			`uniform float environmentLuminance;`
			`uniform vec3 lightPosition;`
			`uniform vec3 lightColor;`
			`uniform float lightIntensity;`
			`uniform float clearCoatIOR;`
			`uniform vec3 cameraPosition;`


			`uniform float metallic;`


			`#include "physically_based_shading.shader"`





			`#define TEXTURED_MATERIAL 1`

			`out vec4 fragmentColor;`

			`in vec2 v_uv;`




			`uniform float reflectance;`



			`uniform float anisotropy;`



			`uniform float roughness;`



			`uniform sampler2D diffuseSampler;`
			`uniform sampler2D normalSampler;`
			`uniform sampler2D tangentSampler;`
			`uniform sampler2D infoSampler;`

			`uniform sampler2D ambientOcclusionSampler;`
			`uniform sampler2D materialSampler;`
			`uniform sampler2D shadowNoiseSampler;`
			`uniform sampler2D shadowDepthSampler;`






			`uniform float luma_z;`
			`uniform float far;`


			`uniform mat4 InvProjection;`
			`uniform mat4 lightViewProjection;`
			`uniform vec2 screenSize;`
			`uniform float shadowBias;`

			`const float PackUpscale = 256. / 255.; // fraction -> 0..1 (including 1)`
			`const float UnpackDownscale = 255. / 256.; // 0..1 -> fraction (excluding 1)`

			`const vec3 PackFactors = vec3( 256. * 256. * 256., 256. * 256., 256. );`
			`const vec4 UnpackFactors = UnpackDownscale / vec4( PackFactors, 1. );`

			`const float ShiftRight8 = 1. / 256.;`

			`vec4 packDepthToRGBA( const in float v ) {`
			`vec4 r = vec4( fract( v * PackFactors ), v );`
			`r.yzw -= r.xyz * ShiftRight8; // tidy overflow`
			`return r * PackUpscale;`
			`}`

			`float unpackRGBAToDepth( const in vec4 v ) {`
			`return dot( v, UnpackFactors );`
			`}`



			`float shadow_sample(sampler2D depthMap, vec2 coord)`
			`{`
			`return ( texture(depthMap, coord.xy).x );//DecodeFloatRGBA() ;`
			`}`

			`vec2 DoubleSampleRotated(sampler2D depthMap, vec4 p, vec4 rotMatr, vec4 kernel) {`

			`vec4 rotatedOff;`

			`rotatedOff = rotMatr.xyzw * kernel.xxww +`
			`rotMatr.zwxy * kernel.yyzz;`

			`vec4 fetchPos = p.xyxy + rotatedOff;// + rotatedOff`

			`vec2 result;`

			`result.x = shadow_sample(depthMap, fetchPos.xy);`
			`result.y = shadow_sample(depthMap, fetchPos.zw);`


			`return result;`
			`}`



			`float PCF(sampler2D depthMap, vec4 p, vec2 randDirTC, float depth)`
			`{`

			`vec2 kernelRadius = vec2(4.0);`

			`vec4 irreg_kernel_2d[8];`
			`irreg_kernel_2d[0] = vec4(-0.556641,-0.037109,-0.654297, 0.111328);`
			`irreg_kernel_2d[1] = vec4(0.173828,0.111328,0.064453, -0.359375);`
			`irreg_kernel_2d[2] = vec4(0.001953,0.082031,-0.060547, 0.078125);`
			`irreg_kernel_2d[3] = vec4(0.220703,-0.359375,-0.062500, 0.001953);`
			`irreg_kernel_2d[4] = vec4(0.242188,0.126953,-0.250000, -0.140625);`
			`irreg_kernel_2d[5] = vec4(0.070313,-0.025391,0.148438, 0.082031);`
			`irreg_kernel_2d[6] = vec4(-0.078125,0.013672,-0.314453, 0.013672);`
			`irreg_kernel_2d[7] = vec4(0.117188,-0.140625,-0.199219, 0.117188);`

			`vec2 vInvShadowMapWH = vec2(1.0 / 2048.0);`

			`const int kernelSize = 8;`

			`mediump float P_Z = depth; // p.z;`

			`vec4 p0 = vec4(p.xyz, 1.0);`


			`mediump vec2 rotScale = vec2(kernelRadius.y * 2.0);`

			`float shadowTest = 0.0;`

			`#define KERNEL_STEP_SIZE 2`

			`vec2 rotSample = 2.0 * texture(shadowDepthSampler, randDirTC.xy).xy - 1.0;`
			`rotSample.xy = normalize(rotSample.xy);`
			`rotSample.xy = (kernelRadius.xy vInvShadowMapWH.xy);`

			`vec4 rot = vec4(rotSample.x, -rotSample.y, rotSample.y, rotSample.x);`

			`const int kernelOffset = 0;`

			`for(int i=kernelOffset; i<kernelSize; i+=KERNEL_STEP_SIZE) // Loop over taps`
			`{`

			`mediump vec4 sampleDepth = vec4(0.0);`
			`vec4 irr = irreg_kernel_2d[i+0];`
			`sampleDepth.xy = DoubleSampleRotated(depthMap, p0, rot, irr);`
			`sampleDepth.zw = DoubleSampleRotated(depthMap, p0, rot, irreg_kernel_2d[i+1]);`

			`mediump vec4 InShadow;`
			`InShadow.x = ( P_Z < sampleDepth.x + shadowBias ) ? 1. : 0.0;`
			`InShadow.y = ( P_Z < sampleDepth.y + shadowBias ) ? 1. : 0.0;`
			`InShadow.z = ( P_Z < sampleDepth.z + shadowBias ) ? 1. : 0.0;`
			`InShadow.w = ( P_Z < sampleDepth.w + shadowBias ) ? 1. : 0.0;`


			`const mediump float quality = 8.0; // 8 == high`
			`const mediump float fInvSamplNum = (1.0 / quality);`

			`shadowTest += dot(InShadow, vec4(fInvSamplNum));`
			`}`

			`return shadowTest;`
			`}`

			`float DecodeFloatRGBA( vec4 rgba ) {`
			`return (rgba).x;`

			`//return dot( rgba, vec4(1.0, 1.0 / 255.0, 1.0 / 65025.0, 1.0 / 160581375.0) );`
			`}`

			`float poissonPCFmultitap(vec4 projCoords, float shadowDepth, vec2 uv)`
			`{`
			`const mediump float step = 1.0 - 1.0 / 8.0;`
			`const mediump float fScale = 0.025; // 0.025`

			`mediump float n = 0.0;`

			`mediump vec3 directions[8];`
			`float vSampleScale = 1.0 / 2048.0;`


			`directions[0] = normalize(vec3( 1.0, 1.0, 1.0))fScale(n+=step);`
			`directions[1] = normalize(vec3(-1.0,-1.0,-1.0))fScale(n+=step);`
			`directions[2] = normalize(vec3(-1.0,-1.0, 1.0))fScale(n+=step);`
			`directions[3] = normalize(vec3(-1.0, 1.0,-1.0))fScale(n+=step);`
			`directions[4] = normalize(vec3(-1.0, 1.0 ,1.0))fScale(n+=step);`
			`directions[5] = normalize(vec3( 1.0,-1.0,-1.0))fScale(n+=step);`
			`directions[6] = normalize(vec3( 1.0,-1.0, 1.0))fScale(n+=step);`
			`directions[7] = normalize(vec3( 1.0, 1.0,-1.0))fScale(n+=step);`

			`mediump vec3 randomSample = texture(shadowNoiseSampler, vec2(64.0, 64.0) * uv.xy / 4.0).xyz * 2.0 - 1.0;`



			`float sum = 0.0;`

			`for( int i = 0; i < 4; i++ ) {`
			`vec3 sampler = reflect(directions[0], randomSample) * vSampleScale;`

			`float pixelDepth = DecodeFloatRGBA( texture(shadowDepthSampler, projCoords.xy+ sampler.xy ) ) ; // + sampler.xy + sampler.z`

			`if( pixelDepth + shadowBias > shadowDepth) {`
			`sum += 1.0;`
			`} else {`
			`sum += 0.0;`
			`}`
			`}`

			`return sum;`
			`}`

			`float linestep(float min, float max, float value) {`
			`return clamp((value - min) / (max - min), 0., 1.);`
			`}`

			`float reduceBleeding(float p_max, float amount) {`
			`return linestep(amount, 1.0, p_max);`
			`}`

			`float ChebyshevUpperBound(vec2 moments, float distance) {`
			`if (distance <= moments.x)`
			`return 1.0;`

			`float g_minVariance = .0007;`

			`float variance = moments.y - (moments.x*moments.x);`
			`variance = max(variance,g_minVariance);`

			`float d = distance - moments.x;`
			`float p_max = variance / (variance + d*d);`

			`return reduceBleeding(p_max, shadowBias);`
			`}`

			`float calculateShadowOcclusion( vec3 worldPosition, vec2 uv ) {`

			`vec4 projCoords = lightViewProjection * vec4(worldPosition, 1.0) ;`

			`float shadowDepth = length( lightPosition - worldPosition ) / 99.0;`

			`projCoords.xy /= projCoords.w;`
			`projCoords = 0.51 * projCoords + 0.5;`

			`vec4 moments = texture( shadowDepthSampler, projCoords.xy );`
			`mediump vec2 randomSample = texture(shadowNoiseSampler, vec2(1024.) * uv / 64.0).xy * 2.0 - 1.0;`

			`float outFrustum = 0.0;`

			`if(projCoords.x < 0.0 \|\| projCoords.x > 1.0) {`
			`return 0.0;`
			`}`

			`if(projCoords.y < 0.0 \|\| projCoords.y > 1.0) {`
			`return 0.0;`
			`}`

			`if(projCoords.z < 1.0) {`
			`return 0.0;`
			`}`

			`return ChebyshevUpperBound(moments.xy, shadowDepth);`
			`return poissonPCFmultitap(projCoords, shadowDepth, uv);`
			`//return PCF( shadowDepthSampler, projCoords, randomSample, shadowDepth );`


			`}`

			`vec3 sampleReflection( vec3 r ) {`

			`return texture(reflectionSampler, r).xyz;`

			`}`

			`vec3 cubemapReflection( deferredMaterialData materialData ) {`

			`vec3 viewDir = ( cameraPosition - materialData.position );`
			`vec3 reflectionVector = reflect(-viewDir, normalize( materialData.normal ));`
			`vec3 reflectionSample = sampleReflection( reflectionVector );`

			`return reflectionSample;`
			`}`


			`const float gamma = 2.2;`

			`float toLinear(float v) {`
			`return pow(v, gamma);`
			`}`

			`vec2 toLinear(vec2 v) {`
			`return pow(v, vec2(gamma));`
			`}`

			`vec3 toLinear(vec3 v) {`
			`return pow(v, vec3(gamma));`
			`}`

			`vec4 toLinear(vec4 v) {`
			`return vec4(toLinear(v.rgb), v.a);`
			`}`


			`vec3 HDR_ACES(const vec3 x) {`
			`// Narkowicz 2015, "ACES Filmic Tone Mapping Curve"`
			`const float a = 2.51;`
			`const float b = 0.03;`
			`const float c = 2.43;`
			`const float d = 0.59;`
			`const float e = 0.14;`
			`return (x * (a * x + b)) / (x * (c * x + d) + e);`
			`}`

			`vec3 tonemap(const vec3 x) {`
			`return HDR_ACES(x);`
			`}`

			`float linearToSRGB(float c) {`
			`return (c <= 0.0031308) ? c * 12.92 : (pow(abs(c), 1.0 / 2.4) * 1.055) - 0.055;`
			`}`

			`vec3 linearToSRGB(vec3 c) {`
			`return vec3(linearToSRGB(c.r), linearToSRGB(c.g), linearToSRGB(c.b));`
			`}`


			`void main() {`

			`deferredMaterialData materialData;`

			`float gamma = 2.2;`

			`vec4 normalDepth = texture(normalSampler, v_uv);`
			`vec4 diffuseRoughness = texture(diffuseSampler, v_uv);`
			`vec4 positionMaterialIndex = texture(infoSampler, v_uv);`
			`vec4 depthNormal = texture(normalSampler, v_uv);`
			`vec4 shadowAmbientOcclusion = texture(ambientOcclusionSampler, v_uv);`

			`materialData.ambientOcclusion = shadowAmbientOcclusion.x;`
			`materialData.normal = normalize( depthNormal.xyz );`
			`materialData.baseColor = sRGBtoLinear(diffuseRoughness.rgb);`
			`materialData.position = positionMaterialIndex.xyz;`
			`materialData.index = positionMaterialIndex.w;`
			`materialData.roughness = diffuseRoughness.w;`
			`materialData.alpha = 1.0;`
			`materialData.shadowOcclusion = shadowAmbientOcclusion.y; //calculateShadowOcclusion( materialData.position, v_uv );`
			`materialData.metallic = metallic;`
			`materialData.reflectance = reflectance;`
			`//materialData.tangent = tangent;`

			`//materialData.shadowOcclusion = 1.0;`
			`//materialData.baseColor = vec3(1.0);`

			`vec4 color = physically_based_shading( materialData );`

			`float exposure = 1.7;`

			`color.rgb *= exposure;`

			`vec3 finalRender = color.rgb;// + diffuse * .2`



			`// For fxaa`
			`float luma = sqrt( dot(color.rgb, vec3(0.299, 0.587, 0.114)) );`

			`if(luma_z == 1.0)`

			`//if(v_uv.x < 0.5)`
			`fragmentColor = vec4(linearToSRGB(tonemap(color.rgb)), luma);`
			`//else`
			`// fragmentColor = vec4(vec3(materialData.ambientOcclusion), 1.0);`

			`//fragmentColor = vec4(linearToSRGB(tonemap(color.rgb)), 1.0);`

			`if(materialData.index == 100.0) {`

			`vec3 cubeReflectionSample = cubemapReflection( materialData );`
			`fragmentColor = vec4( cubeReflectionSample, 1.0 );`

			`}`

			`}`