node-ejs-renderer/node_modules/three/examples/jsm/objects/Water2.js

import {
	Clock,
	Color,
	Matrix4,
	Mesh,
	RepeatWrapping,
	ShaderMaterial,
	TextureLoader,
	UniformsLib,
	UniformsUtils,
	Vector2,
	Vector4
} from 'three';
import { Reflector } from '../objects/Reflector.js';
import { Refractor } from '../objects/Refractor.js';

/**
 * References:
 *	https://alex.vlachos.com/graphics/Vlachos-SIGGRAPH10-WaterFlow.pdf
 *	http://graphicsrunner.blogspot.de/2010/08/water-using-flow-maps.html
 *
 */

class Water extends Mesh {

	constructor( geometry, options = {} ) {

		super( geometry );

		this.isWater = true;

		this.type = 'Water';

		const scope = this;

		const color = ( options.color !== undefined ) ? new Color( options.color ) : new Color( 0xFFFFFF );
		const textureWidth = options.textureWidth !== undefined ? options.textureWidth : 512;
		const textureHeight = options.textureHeight !== undefined ? options.textureHeight : 512;
		const clipBias = options.clipBias !== undefined ? options.clipBias : 0;
		const flowDirection = options.flowDirection !== undefined ? options.flowDirection : new Vector2( 1, 0 );
		const flowSpeed = options.flowSpeed !== undefined ? options.flowSpeed : 0.03;
		const reflectivity = options.reflectivity !== undefined ? options.reflectivity : 0.02;
		const scale = options.scale !== undefined ? options.scale : 1;
		const shader = options.shader !== undefined ? options.shader : Water.WaterShader;

		const textureLoader = new TextureLoader();

		const flowMap = options.flowMap || undefined;
		const normalMap0 = options.normalMap0 || textureLoader.load( 'textures/water/Water_1_M_Normal.jpg' );
		const normalMap1 = options.normalMap1 || textureLoader.load( 'textures/water/Water_2_M_Normal.jpg' );

		const cycle = 0.15; // a cycle of a flow map phase
		const halfCycle = cycle * 0.5;
		const textureMatrix = new Matrix4();
		const clock = new Clock();

		// internal components

		if ( Reflector === undefined ) {

			console.error( 'THREE.Water: Required component Reflector not found.' );
			return;

		}

		if ( Refractor === undefined ) {

			console.error( 'THREE.Water: Required component Refractor not found.' );
			return;

		}

		const reflector = new Reflector( geometry, {
			textureWidth: textureWidth,
			textureHeight: textureHeight,
			clipBias: clipBias
		} );

		const refractor = new Refractor( geometry, {
			textureWidth: textureWidth,
			textureHeight: textureHeight,
			clipBias: clipBias
		} );

		reflector.matrixAutoUpdate = false;
		refractor.matrixAutoUpdate = false;

		// material

		this.material = new ShaderMaterial( {
			name: shader.name,
			uniforms: UniformsUtils.merge( [
				UniformsLib[ 'fog' ],
				shader.uniforms
			] ),
			vertexShader: shader.vertexShader,
			fragmentShader: shader.fragmentShader,
			transparent: true,
			fog: true
		} );

		if ( flowMap !== undefined ) {

			this.material.defines.USE_FLOWMAP = '';
			this.material.uniforms[ 'tFlowMap' ] = {
				type: 't',
				value: flowMap
			};

		} else {

			this.material.uniforms[ 'flowDirection' ] = {
				type: 'v2',
				value: flowDirection
			};

		}

		// maps

		normalMap0.wrapS = normalMap0.wrapT = RepeatWrapping;
		normalMap1.wrapS = normalMap1.wrapT = RepeatWrapping;

		this.material.uniforms[ 'tReflectionMap' ].value = reflector.getRenderTarget().texture;
		this.material.uniforms[ 'tRefractionMap' ].value = refractor.getRenderTarget().texture;
		this.material.uniforms[ 'tNormalMap0' ].value = normalMap0;
		this.material.uniforms[ 'tNormalMap1' ].value = normalMap1;

		// water

		this.material.uniforms[ 'color' ].value = color;
		this.material.uniforms[ 'reflectivity' ].value = reflectivity;
		this.material.uniforms[ 'textureMatrix' ].value = textureMatrix;

		// inital values

		this.material.uniforms[ 'config' ].value.x = 0; // flowMapOffset0
		this.material.uniforms[ 'config' ].value.y = halfCycle; // flowMapOffset1
		this.material.uniforms[ 'config' ].value.z = halfCycle; // halfCycle
		this.material.uniforms[ 'config' ].value.w = scale; // scale

		// functions

		function updateTextureMatrix( camera ) {

			textureMatrix.set(
				0.5, 0.0, 0.0, 0.5,
				0.0, 0.5, 0.0, 0.5,
				0.0, 0.0, 0.5, 0.5,
				0.0, 0.0, 0.0, 1.0
			);

			textureMatrix.multiply( camera.projectionMatrix );
			textureMatrix.multiply( camera.matrixWorldInverse );
			textureMatrix.multiply( scope.matrixWorld );

		}

		function updateFlow() {

			const delta = clock.getDelta();
			const config = scope.material.uniforms[ 'config' ];

			config.value.x += flowSpeed * delta; // flowMapOffset0
			config.value.y = config.value.x + halfCycle; // flowMapOffset1

			// Important: The distance between offsets should be always the value of "halfCycle".
			// Moreover, both offsets should be in the range of [ 0, cycle ].
			// This approach ensures a smooth water flow and avoids "reset" effects.

			if ( config.value.x >= cycle ) {

				config.value.x = 0;
				config.value.y = halfCycle;

			} else if ( config.value.y >= cycle ) {

				config.value.y = config.value.y - cycle;

			}

		}

		//

		this.onBeforeRender = function ( renderer, scene, camera ) {

			updateTextureMatrix( camera );
			updateFlow();

			scope.visible = false;

			reflector.matrixWorld.copy( scope.matrixWorld );
			refractor.matrixWorld.copy( scope.matrixWorld );

			reflector.onBeforeRender( renderer, scene, camera );
			refractor.onBeforeRender( renderer, scene, camera );

			scope.visible = true;

		};

	}

}

Water.WaterShader = {

	name: 'WaterShader',

	uniforms: {

		'color': {
			type: 'c',
			value: null
		},

		'reflectivity': {
			type: 'f',
			value: 0
		},

		'tReflectionMap': {
			type: 't',
			value: null
		},

		'tRefractionMap': {
			type: 't',
			value: null
		},

		'tNormalMap0': {
			type: 't',
			value: null
		},

		'tNormalMap1': {
			type: 't',
			value: null
		},

		'textureMatrix': {
			type: 'm4',
			value: null
		},

		'config': {
			type: 'v4',
			value: new Vector4()
		}

	},

	vertexShader: /* glsl */`

		#include <common>
		#include <fog_pars_vertex>
		#include <logdepthbuf_pars_vertex>

		uniform mat4 textureMatrix;

		varying vec4 vCoord;
		varying vec2 vUv;
		varying vec3 vToEye;

		void main() {

			vUv = uv;
			vCoord = textureMatrix * vec4( position, 1.0 );

			vec4 worldPosition = modelMatrix * vec4( position, 1.0 );
			vToEye = cameraPosition - worldPosition.xyz;

			vec4 mvPosition =  viewMatrix * worldPosition; // used in fog_vertex
			gl_Position = projectionMatrix * mvPosition;

			#include <logdepthbuf_vertex>
			#include <fog_vertex>

		}`,

	fragmentShader: /* glsl */`

		#include <common>
		#include <fog_pars_fragment>
		#include <logdepthbuf_pars_fragment>

		uniform sampler2D tReflectionMap;
		uniform sampler2D tRefractionMap;
		uniform sampler2D tNormalMap0;
		uniform sampler2D tNormalMap1;

		#ifdef USE_FLOWMAP
			uniform sampler2D tFlowMap;
		#else
			uniform vec2 flowDirection;
		#endif

		uniform vec3 color;
		uniform float reflectivity;
		uniform vec4 config;

		varying vec4 vCoord;
		varying vec2 vUv;
		varying vec3 vToEye;

		void main() {

			#include <logdepthbuf_fragment>

			float flowMapOffset0 = config.x;
			float flowMapOffset1 = config.y;
			float halfCycle = config.z;
			float scale = config.w;

			vec3 toEye = normalize( vToEye );

			// determine flow direction
			vec2 flow;
			#ifdef USE_FLOWMAP
				flow = texture2D( tFlowMap, vUv ).rg * 2.0 - 1.0;
			#else
				flow = flowDirection;
			#endif
			flow.x *= - 1.0;

			// sample normal maps (distort uvs with flowdata)
			vec4 normalColor0 = texture2D( tNormalMap0, ( vUv * scale ) + flow * flowMapOffset0 );
			vec4 normalColor1 = texture2D( tNormalMap1, ( vUv * scale ) + flow * flowMapOffset1 );

			// linear interpolate to get the final normal color
			float flowLerp = abs( halfCycle - flowMapOffset0 ) / halfCycle;
			vec4 normalColor = mix( normalColor0, normalColor1, flowLerp );

			// calculate normal vector
			vec3 normal = normalize( vec3( normalColor.r * 2.0 - 1.0, normalColor.b,  normalColor.g * 2.0 - 1.0 ) );

			// calculate the fresnel term to blend reflection and refraction maps
			float theta = max( dot( toEye, normal ), 0.0 );
			float reflectance = reflectivity + ( 1.0 - reflectivity ) * pow( ( 1.0 - theta ), 5.0 );

			// calculate final uv coords
			vec3 coord = vCoord.xyz / vCoord.w;
			vec2 uv = coord.xy + coord.z * normal.xz * 0.05;

			vec4 reflectColor = texture2D( tReflectionMap, vec2( 1.0 - uv.x, uv.y ) );
			vec4 refractColor = texture2D( tRefractionMap, uv );

			// multiply water color with the mix of both textures
			gl_FragColor = vec4( color, 1.0 ) * mix( refractColor, reflectColor, reflectance );

			#include <tonemapping_fragment>
			#include <colorspace_fragment>
			#include <fog_fragment>

		}`

};

export { Water };
Main initial commit 2024-06-09 13:55:01 -04:00			`import {`
			`Clock,`
			`Color,`
			`Matrix4,`
			`Mesh,`
			`RepeatWrapping,`
			`ShaderMaterial,`
			`TextureLoader,`
			`UniformsLib,`
			`UniformsUtils,`
			`Vector2,`
			`Vector4`
			`} from 'three';`
			`import { Reflector } from '../objects/Reflector.js';`
			`import { Refractor } from '../objects/Refractor.js';`

			`/**`
			`* References:`
			`* https://alex.vlachos.com/graphics/Vlachos-SIGGRAPH10-WaterFlow.pdf`
			`* http://graphicsrunner.blogspot.de/2010/08/water-using-flow-maps.html`
			`*`
			`*/`

			`class Water extends Mesh {`

			`constructor( geometry, options = {} ) {`

			`super( geometry );`

			`this.isWater = true;`

			`this.type = 'Water';`

			`const scope = this;`

			`const color = ( options.color !== undefined ) ? new Color( options.color ) : new Color( 0xFFFFFF );`
			`const textureWidth = options.textureWidth !== undefined ? options.textureWidth : 512;`
			`const textureHeight = options.textureHeight !== undefined ? options.textureHeight : 512;`
			`const clipBias = options.clipBias !== undefined ? options.clipBias : 0;`
			`const flowDirection = options.flowDirection !== undefined ? options.flowDirection : new Vector2( 1, 0 );`
			`const flowSpeed = options.flowSpeed !== undefined ? options.flowSpeed : 0.03;`
			`const reflectivity = options.reflectivity !== undefined ? options.reflectivity : 0.02;`
			`const scale = options.scale !== undefined ? options.scale : 1;`
			`const shader = options.shader !== undefined ? options.shader : Water.WaterShader;`

			`const textureLoader = new TextureLoader();`

			`const flowMap = options.flowMap \|\| undefined;`
			`const normalMap0 = options.normalMap0 \|\| textureLoader.load( 'textures/water/Water_1_M_Normal.jpg' );`
			`const normalMap1 = options.normalMap1 \|\| textureLoader.load( 'textures/water/Water_2_M_Normal.jpg' );`

			`const cycle = 0.15; // a cycle of a flow map phase`
			`const halfCycle = cycle * 0.5;`
			`const textureMatrix = new Matrix4();`
			`const clock = new Clock();`

			`// internal components`

			`if ( Reflector === undefined ) {`

			`console.error( 'THREE.Water: Required component Reflector not found.' );`
			`return;`

			`}`

			`if ( Refractor === undefined ) {`

			`console.error( 'THREE.Water: Required component Refractor not found.' );`
			`return;`

			`}`

			`const reflector = new Reflector( geometry, {`
			`textureWidth: textureWidth,`
			`textureHeight: textureHeight,`
			`clipBias: clipBias`
			`} );`

			`const refractor = new Refractor( geometry, {`
			`textureWidth: textureWidth,`
			`textureHeight: textureHeight,`
			`clipBias: clipBias`
			`} );`

			`reflector.matrixAutoUpdate = false;`
			`refractor.matrixAutoUpdate = false;`

			`// material`

			`this.material = new ShaderMaterial( {`
			`name: shader.name,`
			`uniforms: UniformsUtils.merge( [`
			`UniformsLib[ 'fog' ],`
			`shader.uniforms`
			`] ),`
			`vertexShader: shader.vertexShader,`
			`fragmentShader: shader.fragmentShader,`
			`transparent: true,`
			`fog: true`
			`} );`

			`if ( flowMap !== undefined ) {`

			`this.material.defines.USE_FLOWMAP = '';`
			`this.material.uniforms[ 'tFlowMap' ] = {`
			`type: 't',`
			`value: flowMap`
			`};`

			`} else {`

			`this.material.uniforms[ 'flowDirection' ] = {`
			`type: 'v2',`
			`value: flowDirection`
			`};`

			`}`

			`// maps`

			`normalMap0.wrapS = normalMap0.wrapT = RepeatWrapping;`
			`normalMap1.wrapS = normalMap1.wrapT = RepeatWrapping;`

			`this.material.uniforms[ 'tReflectionMap' ].value = reflector.getRenderTarget().texture;`
			`this.material.uniforms[ 'tRefractionMap' ].value = refractor.getRenderTarget().texture;`
			`this.material.uniforms[ 'tNormalMap0' ].value = normalMap0;`
			`this.material.uniforms[ 'tNormalMap1' ].value = normalMap1;`

			`// water`

			`this.material.uniforms[ 'color' ].value = color;`
			`this.material.uniforms[ 'reflectivity' ].value = reflectivity;`
			`this.material.uniforms[ 'textureMatrix' ].value = textureMatrix;`

			`// inital values`

			`this.material.uniforms[ 'config' ].value.x = 0; // flowMapOffset0`
			`this.material.uniforms[ 'config' ].value.y = halfCycle; // flowMapOffset1`
			`this.material.uniforms[ 'config' ].value.z = halfCycle; // halfCycle`
			`this.material.uniforms[ 'config' ].value.w = scale; // scale`

			`// functions`

			`function updateTextureMatrix( camera ) {`

			`textureMatrix.set(`
			`0.5, 0.0, 0.0, 0.5,`
			`0.0, 0.5, 0.0, 0.5,`
			`0.0, 0.0, 0.5, 0.5,`
			`0.0, 0.0, 0.0, 1.0`
			`);`

			`textureMatrix.multiply( camera.projectionMatrix );`
			`textureMatrix.multiply( camera.matrixWorldInverse );`
			`textureMatrix.multiply( scope.matrixWorld );`

			`}`

			`function updateFlow() {`

			`const delta = clock.getDelta();`
			`const config = scope.material.uniforms[ 'config' ];`

			`config.value.x += flowSpeed * delta; // flowMapOffset0`
			`config.value.y = config.value.x + halfCycle; // flowMapOffset1`

			`// Important: The distance between offsets should be always the value of "halfCycle".`
			`// Moreover, both offsets should be in the range of [ 0, cycle ].`
			`// This approach ensures a smooth water flow and avoids "reset" effects.`

			`if ( config.value.x >= cycle ) {`

			`config.value.x = 0;`
			`config.value.y = halfCycle;`

			`} else if ( config.value.y >= cycle ) {`

			`config.value.y = config.value.y - cycle;`

			`}`

			`}`

			`//`

			`this.onBeforeRender = function ( renderer, scene, camera ) {`

			`updateTextureMatrix( camera );`
			`updateFlow();`

			`scope.visible = false;`

			`reflector.matrixWorld.copy( scope.matrixWorld );`
			`refractor.matrixWorld.copy( scope.matrixWorld );`

			`reflector.onBeforeRender( renderer, scene, camera );`
			`refractor.onBeforeRender( renderer, scene, camera );`

			`scope.visible = true;`

			`};`

			`}`

			`}`

			`Water.WaterShader = {`

			`name: 'WaterShader',`

			`uniforms: {`

			`'color': {`
			`type: 'c',`
			`value: null`
			`},`

			`'reflectivity': {`
			`type: 'f',`
			`value: 0`
			`},`

			`'tReflectionMap': {`
			`type: 't',`
			`value: null`
			`},`

			`'tRefractionMap': {`
			`type: 't',`
			`value: null`
			`},`

			`'tNormalMap0': {`
			`type: 't',`
			`value: null`
			`},`

			`'tNormalMap1': {`
			`type: 't',`
			`value: null`
			`},`

			`'textureMatrix': {`
			`type: 'm4',`
			`value: null`
			`},`

			`'config': {`
			`type: 'v4',`
			`value: new Vector4()`
			`}`

			`},`

			vertexShader: /* glsl */`

			`#include <common>`
			`#include <fog_pars_vertex>`
			`#include <logdepthbuf_pars_vertex>`

			`uniform mat4 textureMatrix;`

			`varying vec4 vCoord;`
			`varying vec2 vUv;`
			`varying vec3 vToEye;`

			`void main() {`

			`vUv = uv;`
			`vCoord = textureMatrix * vec4( position, 1.0 );`

			`vec4 worldPosition = modelMatrix * vec4( position, 1.0 );`
			`vToEye = cameraPosition - worldPosition.xyz;`

			`vec4 mvPosition = viewMatrix * worldPosition; // used in fog_vertex`
			`gl_Position = projectionMatrix * mvPosition;`

			`#include <logdepthbuf_vertex>`
			`#include <fog_vertex>`

			}`,

			fragmentShader: /* glsl */`

			`#include <common>`
			`#include <fog_pars_fragment>`
			`#include <logdepthbuf_pars_fragment>`

			`uniform sampler2D tReflectionMap;`
			`uniform sampler2D tRefractionMap;`
			`uniform sampler2D tNormalMap0;`
			`uniform sampler2D tNormalMap1;`

			`#ifdef USE_FLOWMAP`
			`uniform sampler2D tFlowMap;`
			`#else`
			`uniform vec2 flowDirection;`
			`#endif`

			`uniform vec3 color;`
			`uniform float reflectivity;`
			`uniform vec4 config;`

			`varying vec4 vCoord;`
			`varying vec2 vUv;`
			`varying vec3 vToEye;`

			`void main() {`

			`#include <logdepthbuf_fragment>`

			`float flowMapOffset0 = config.x;`
			`float flowMapOffset1 = config.y;`
			`float halfCycle = config.z;`
			`float scale = config.w;`

			`vec3 toEye = normalize( vToEye );`

			`// determine flow direction`
			`vec2 flow;`
			`#ifdef USE_FLOWMAP`
			`flow = texture2D( tFlowMap, vUv ).rg * 2.0 - 1.0;`
			`#else`
			`flow = flowDirection;`
			`#endif`
			`flow.x *= - 1.0;`

			`// sample normal maps (distort uvs with flowdata)`
			`vec4 normalColor0 = texture2D( tNormalMap0, ( vUv * scale ) + flow * flowMapOffset0 );`
			`vec4 normalColor1 = texture2D( tNormalMap1, ( vUv * scale ) + flow * flowMapOffset1 );`

			`// linear interpolate to get the final normal color`
			`float flowLerp = abs( halfCycle - flowMapOffset0 ) / halfCycle;`
			`vec4 normalColor = mix( normalColor0, normalColor1, flowLerp );`

			`// calculate normal vector`
			`vec3 normal = normalize( vec3( normalColor.r * 2.0 - 1.0, normalColor.b, normalColor.g * 2.0 - 1.0 ) );`

			`// calculate the fresnel term to blend reflection and refraction maps`
			`float theta = max( dot( toEye, normal ), 0.0 );`
			`float reflectance = reflectivity + ( 1.0 - reflectivity ) * pow( ( 1.0 - theta ), 5.0 );`

			`// calculate final uv coords`
			`vec3 coord = vCoord.xyz / vCoord.w;`
			`vec2 uv = coord.xy + coord.z * normal.xz * 0.05;`

			`vec4 reflectColor = texture2D( tReflectionMap, vec2( 1.0 - uv.x, uv.y ) );`
			`vec4 refractColor = texture2D( tRefractionMap, uv );`

			`// multiply water color with the mix of both textures`
			`gl_FragColor = vec4( color, 1.0 ) * mix( refractColor, reflectColor, reflectance );`

			`#include <tonemapping_fragment>`
			`#include <colorspace_fragment>`
			`#include <fog_fragment>`

			}`

			`};`

			`export { Water };`