summit/frontend/node_modules/three-stdlib/shaders/SSRShader.js

import { Vector2, Matrix4 } from "three";
const SSRShader = {
  defines: {
    MAX_STEP: 0,
    isPerspectiveCamera: true,
    isDistanceAttenuation: true,
    isFresnel: true,
    isInfiniteThick: false,
    isSelective: false
  },
  uniforms: {
    tDiffuse: { value: null },
    tNormal: { value: null },
    tMetalness: { value: null },
    tDepth: { value: null },
    cameraNear: { value: null },
    cameraFar: { value: null },
    resolution: { value: /* @__PURE__ */ new Vector2() },
    cameraProjectionMatrix: { value: /* @__PURE__ */ new Matrix4() },
    cameraInverseProjectionMatrix: { value: /* @__PURE__ */ new Matrix4() },
    opacity: { value: 0.5 },
    maxDistance: { value: 180 },
    cameraRange: { value: 0 },
    surfDist: { value: 7e-3 },
    thickTolerance: { value: 0.03 }
  },
  vertexShader: (
    /* glsl */
    `

    varying vec2 vUv;

    void main() {

			vUv = uv;

			gl_Position = projectionMatrix * modelViewMatrix * vec4( position, 1.0 );

    }

  `
  ),
  fragmentShader: (
    /* glsl */
    `
		// precision highp float;
		precision highp sampler2D;
		varying vec2 vUv;
		uniform sampler2D tDepth;
		uniform sampler2D tNormal;
		uniform sampler2D tMetalness;
		uniform sampler2D tDiffuse;
		uniform float cameraRange;
		uniform vec2 resolution;
		uniform float opacity;
		uniform float cameraNear;
		uniform float cameraFar;
		uniform float maxDistance;
		uniform float surfDist;
		uniform mat4 cameraProjectionMatrix;
		uniform mat4 cameraInverseProjectionMatrix;
		uniform float thickTolerance;
		#include <packing>
		float pointToLineDistance(vec3 x0, vec3 x1, vec3 x2) {
			//x0: point, x1: linePointA, x2: linePointB
			//https://mathworld.wolfram.com/Point-LineDistance3-Dimensional.html
			return length(cross(x0-x1,x0-x2))/length(x2-x1);
		}
		float pointPlaneDistance(vec3 point,vec3 planePoint,vec3 planeNormal){
			// https://mathworld.wolfram.com/Point-PlaneDistance.html
			//// https://en.wikipedia.org/wiki/Plane_(geometry)
			//// http://paulbourke.net/geometry/pointlineplane/
			float a=planeNormal.x,b=planeNormal.y,c=planeNormal.z;
			float x0=point.x,y0=point.y,z0=point.z;
			float x=planePoint.x,y=planePoint.y,z=planePoint.z;
			float d=-(a*x+b*y+c*z);
			float distance=(a*x0+b*y0+c*z0+d)/sqrt(a*a+b*b+c*c);
			return distance;
		}
		float getDepth( const in vec2 uv ) {
			return texture2D( tDepth, uv ).x;
		}
		float getViewZ( const in float depth ) {
			#ifdef isPerspectiveCamera
				return perspectiveDepthToViewZ( depth, cameraNear, cameraFar );
			#else
				return orthographicDepthToViewZ( depth, cameraNear, cameraFar );
			#endif
		}
		vec3 getViewPosition( const in vec2 uv, const in float depth/*clip space*/, const in float clipW ) {
			vec4 clipPosition = vec4( ( vec3( uv, depth ) - 0.5 ) * 2.0, 1.0 );//ndc
			clipPosition *= clipW; //clip
			return ( cameraInverseProjectionMatrix * clipPosition ).xyz;//view
		}
		vec3 getViewNormal( const in vec2 uv ) {
			return unpackRGBToNormal( texture2D( tNormal, uv ).xyz );
		}
		vec2 viewPositionToXY(vec3 viewPosition){
			vec2 xy;
			vec4 clip=cameraProjectionMatrix*vec4(viewPosition,1);
			xy=clip.xy;//clip
			float clipW=clip.w;
			xy/=clipW;//NDC
			xy=(xy+1.)/2.;//uv
			xy*=resolution;//screen
			return xy;
		}
		void main(){
			#ifdef isSelective
				float metalness=texture2D(tMetalness,vUv).r;
				if(metalness==0.) return;
			#endif

			float depth = getDepth( vUv );
			float viewZ = getViewZ( depth );
			if(-viewZ>=cameraFar) return;

			float clipW = cameraProjectionMatrix[2][3] * viewZ+cameraProjectionMatrix[3][3];
			vec3 viewPosition=getViewPosition( vUv, depth, clipW );

			vec2 d0=gl_FragCoord.xy;
			vec2 d1;

			vec3 viewNormal=getViewNormal( vUv );

			#ifdef isPerspectiveCamera
				vec3 viewIncidenceDir=normalize(viewPosition);
				vec3 viewReflectDir=reflect(viewIncidenceDir,viewNormal);
			#else
				vec3 viewIncidenceDir=vec3(0,0,-1);
				vec3 viewReflectDir=reflect(viewIncidenceDir,viewNormal);
			#endif

			float maxReflectRayLen=maxDistance/dot(-viewIncidenceDir,viewNormal);
			// dot(a,b)==length(a)*length(b)*cos(theta) // https://www.mathsisfun.com/algebra/vectors-dot-product.html
			// if(a.isNormalized&&b.isNormalized) dot(a,b)==cos(theta)
			// maxDistance/maxReflectRayLen=cos(theta)
			// maxDistance/maxReflectRayLen==dot(a,b)
			// maxReflectRayLen==maxDistance/dot(a,b)

			vec3 d1viewPosition=viewPosition+viewReflectDir*maxReflectRayLen;
			#ifdef isPerspectiveCamera
				if(d1viewPosition.z>-cameraNear){
					//https://tutorial.math.lamar.edu/Classes/CalcIII/EqnsOfLines.aspx
					float t=(-cameraNear-viewPosition.z)/viewReflectDir.z;
					d1viewPosition=viewPosition+viewReflectDir*t;
				}
			#endif
			d1=viewPositionToXY(d1viewPosition);

			float totalLen=length(d1-d0);
			float xLen=d1.x-d0.x;
			float yLen=d1.y-d0.y;
			float totalStep=max(abs(xLen),abs(yLen));
			float xSpan=xLen/totalStep;
			float ySpan=yLen/totalStep;
			for(float i=0.;i<MAX_STEP;i++){
				if(i>=totalStep) break;
				vec2 xy=vec2(d0.x+i*xSpan,d0.y+i*ySpan);
				if(xy.x<0.||xy.x>resolution.x||xy.y<0.||xy.y>resolution.y) break;
				float s=length(xy-d0)/totalLen;
				vec2 uv=xy/resolution;

				float d = getDepth(uv);
				float vZ = getViewZ( d );
				if(-vZ>=cameraFar) continue;
				float cW = cameraProjectionMatrix[2][3] * vZ+cameraProjectionMatrix[3][3];
				vec3 vP=getViewPosition( uv, d, cW );

				#ifdef isPerspectiveCamera
					// https://www.comp.nus.edu.sg/~lowkl/publications/lowk_persp_interp_techrep.pdf
					float recipVPZ=1./viewPosition.z;
					float viewReflectRayZ=1./(recipVPZ+s*(1./d1viewPosition.z-recipVPZ));
					float sD=surfDist*cW;
				#else
					float viewReflectRayZ=viewPosition.z+s*(d1viewPosition.z-viewPosition.z);
					float sD=surfDist;
				#endif
				if(viewReflectRayZ-sD>vZ) continue;

				#ifdef isInfiniteThick
					if(viewReflectRayZ+thickTolerance*clipW<vP.z) break;
				#endif
				float away=pointToLineDistance(vP,viewPosition,d1viewPosition);

				float op=opacity;

				if(away<sD){
					vec3 vN=getViewNormal( uv );
					if(dot(viewReflectDir,vN)>=0.) continue;
					float distance=pointPlaneDistance(vP,viewPosition,viewNormal);
					if(distance>maxDistance) break;
					#ifdef isDistanceAttenuation
						float ratio=1.-(distance/maxDistance);
						float attenuation=ratio*ratio;
						op=opacity*attenuation;
					#endif
					#ifdef isFresnel
						float fresnel=(dot(viewIncidenceDir,viewReflectDir)+1.)/2.;
						op*=fresnel;
					#endif
					vec4 reflectColor=texture2D(tDiffuse,uv);
					gl_FragColor.xyz=reflectColor.xyz;
					gl_FragColor.a=op;
					break;
				}
			}
		}
	`
  )
};
const SSRDepthShader = {
  defines: {
    PERSPECTIVE_CAMERA: 1
  },
  uniforms: {
    tDepth: { value: null },
    cameraNear: { value: null },
    cameraFar: { value: null }
  },
  vertexShader: (
    /* glsl */
    `

    varying vec2 vUv;

    void main() {

    	vUv = uv;
    	gl_Position = projectionMatrix * modelViewMatrix * vec4( position, 1.0 );

    }

  `
  ),
  fragmentShader: (
    /* glsl */
    `

    uniform sampler2D tDepth;

    uniform float cameraNear;
    uniform float cameraFar;

    varying vec2 vUv;

    #include <packing>

		float getLinearDepth( const in vec2 uv ) {

			#if PERSPECTIVE_CAMERA == 1

				float fragCoordZ = texture2D( tDepth, uv ).x;
				float viewZ = perspectiveDepthToViewZ( fragCoordZ, cameraNear, cameraFar );
				return viewZToOrthographicDepth( viewZ, cameraNear, cameraFar );

			#else

				return texture2D( tDepth, uv ).x;

			#endif

		}

    void main() {

    	float depth = getLinearDepth( vUv );
			float d = 1.0 - depth;
			// d=(d-.999)*1000.;
    	gl_FragColor = vec4( vec3( d ), 1.0 );

    }

  `
  )
};
const SSRBlurShader = {
  uniforms: {
    tDiffuse: { value: null },
    resolution: { value: /* @__PURE__ */ new Vector2() },
    opacity: { value: 0.5 }
  },
  vertexShader: (
    /* glsl */
    `

    varying vec2 vUv;

    void main() {

    	vUv = uv;
    	gl_Position = projectionMatrix * modelViewMatrix * vec4( position, 1.0 );

    }

  `
  ),
  fragmentShader: (
    /* glsl */
    `

    uniform sampler2D tDiffuse;
    uniform vec2 resolution;
    varying vec2 vUv;
    void main() {
			//reverse engineering from PhotoShop blur filter, then change coefficient

    	vec2 texelSize = ( 1.0 / resolution );

			vec4 c=texture2D(tDiffuse,vUv);

			vec2 offset;

			offset=(vec2(-1,0))*texelSize;
			vec4 cl=texture2D(tDiffuse,vUv+offset);

			offset=(vec2(1,0))*texelSize;
			vec4 cr=texture2D(tDiffuse,vUv+offset);

			offset=(vec2(0,-1))*texelSize;
			vec4 cb=texture2D(tDiffuse,vUv+offset);

			offset=(vec2(0,1))*texelSize;
			vec4 ct=texture2D(tDiffuse,vUv+offset);

			// float coeCenter=.5;
			// float coeSide=.125;
			float coeCenter=.2;
			float coeSide=.2;
			float a=c.a*coeCenter+cl.a*coeSide+cr.a*coeSide+cb.a*coeSide+ct.a*coeSide;
			vec3 rgb=(c.rgb*c.a*coeCenter+cl.rgb*cl.a*coeSide+cr.rgb*cr.a*coeSide+cb.rgb*cb.a*coeSide+ct.rgb*ct.a*coeSide)/a;
			gl_FragColor=vec4(rgb,a);

		}
	`
  )
};
export {
  SSRBlurShader,
  SSRDepthShader,
  SSRShader
};
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