nikatlas
/
Tetris3D


			
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							/*
 * @author zz85
 *
 * Experimenting of primitive geometry creation using Surface Parametric equations
 *
 */

THREE.ParametricGeometries = {

	klein: function ( v, u ) {

		u *= Math.PI;
		v *= 2 * Math.PI;

		u = u * 2;
		var x, y, z;
		if ( u < Math.PI ) {

			x = 3 * Math.cos( u ) * ( 1 + Math.sin( u ) ) + ( 2 * ( 1 - Math.cos( u ) / 2 ) ) * Math.cos( u ) * Math.cos( v );
			z = - 8 * Math.sin( u ) - 2 * ( 1 - Math.cos( u ) / 2 ) * Math.sin( u ) * Math.cos( v );

		} else {

			x = 3 * Math.cos( u ) * ( 1 + Math.sin( u ) ) + ( 2 * ( 1 - Math.cos( u ) / 2 ) ) * Math.cos( v + Math.PI );
			z = - 8 * Math.sin( u );

		}

		y = - 2 * ( 1 - Math.cos( u ) / 2 ) * Math.sin( v );

		return new THREE.Vector3( x, y, z );

	},

	plane: function ( width, height ) {

		return function( u, v ) {

			var x = u * width;
			var y = 0;
			var z = v * height;

			return new THREE.Vector3( x, y, z );

		};

	},

	mobius: function( u, t ) {

		// flat mobius strip
		// http://www.wolframalpha.com/input/?i=M%C3%B6bius+strip+parametric+equations&lk=1&a=ClashPrefs_*Surface.MoebiusStrip.SurfaceProperty.ParametricEquations-
		u = u - 0.5;
		var v = 2 * Math.PI * t;

		var x, y, z;

		var a = 2;
		x = Math.cos( v ) * ( a + u * Math.cos( v / 2 ) );
		y = Math.sin( v ) * ( a + u * Math.cos( v / 2 ) );
		z = u * Math.sin( v / 2 );
		return new THREE.Vector3( x, y, z );

	},

	mobius3d: function( u, t ) {

		// volumetric mobius strip
		u *= Math.PI;
		t *= 2 * Math.PI;

		u = u * 2;
		var phi = u / 2;
		var major = 2.25, a = 0.125, b = 0.65;
		var x, y, z;
		x = a * Math.cos( t ) * Math.cos( phi ) - b * Math.sin( t ) * Math.sin( phi );
		z = a * Math.cos( t ) * Math.sin( phi ) + b * Math.sin( t ) * Math.cos( phi );
		y = ( major + x ) * Math.sin( u );
		x = ( major + x ) * Math.cos( u );
		return new THREE.Vector3( x, y, z );

	}

};


/*********************************************
 *
 * Parametric Replacement for TubeGeometry
 *
 *********************************************/

THREE.ParametricGeometries.TubeGeometry = function( path, segments, radius, segmentsRadius, closed, debug ) {

	this.path = path;
	this.segments = segments || 64;
	this.radius = radius || 1;
	this.segmentsRadius = segmentsRadius || 8;
	this.closed = closed || false;
	if ( debug ) this.debug = new THREE.Object3D();


	var scope = this,

		tangent, normal, binormal,

		numpoints = this.segments + 1,

		x, y, z, tx, ty, tz, u, v,

		cx, cy, pos, pos2 = new THREE.Vector3(),
		i, j, ip, jp, a, b, c, d, uva, uvb, uvc, uvd;

	var frames = path.computeFrenetFrames( segments, closed ),
		tangents = frames.tangents,
		normals = frames.normals,
		binormals = frames.binormals;

	// proxy internals
	this.tangents = tangents;
	this.normals = normals;
	this.binormals = binormals;


	var ParametricTube = function( u, v ) {

		v *= 2 * Math.PI;

		i = u * ( numpoints - 1 );
		i = Math.floor( i );

		pos = path.getPointAt( u );

		tangent = tangents[ i ];
		normal = normals[ i ];
		binormal = binormals[ i ];

		if ( scope.debug ) {

			scope.debug.add( new THREE.ArrowHelper( tangent, pos, radius, 0x0000ff ) );
			scope.debug.add( new THREE.ArrowHelper( normal, pos, radius, 0xff0000 ) );
			scope.debug.add( new THREE.ArrowHelper( binormal, pos, radius, 0x00ff00 ) );

		}

		cx = - scope.radius * Math.cos( v ); // TODO: Hack: Negating it so it faces outside.
		cy = scope.radius * Math.sin( v );

		pos2.copy( pos );
		pos2.x += cx * normal.x + cy * binormal.x;
		pos2.y += cx * normal.y + cy * binormal.y;
		pos2.z += cx * normal.z + cy * binormal.z;

		return pos2.clone();

	};

	THREE.ParametricGeometry.call( this, ParametricTube, segments, segmentsRadius );

};

THREE.ParametricGeometries.TubeGeometry.prototype = Object.create( THREE.Geometry.prototype );
THREE.ParametricGeometries.TubeGeometry.prototype.constructor = THREE.ParametricGeometries.TubeGeometry;


 /*********************************************
  *
  * Parametric Replacement for TorusKnotGeometry
  *
  *********************************************/
THREE.ParametricGeometries.TorusKnotGeometry = function ( radius, tube, segmentsT, segmentsR, p, q ) {

	var scope = this;

	this.radius = radius || 200;
	this.tube = tube || 40;
	this.segmentsT = segmentsT || 64;
	this.segmentsR = segmentsR || 8;
	this.p = p || 2;
	this.q = q || 3;

	function TorusKnotCurve() {}

	TorusKnotCurve.prototype = Object.create( THREE.Curve.prototype );
	TorusKnotCurve.prototype.constructor = TorusKnotCurve;

	TorusKnotCurve.prototype.getPoint = function( t ){

		t *= Math.PI * 2;

		var r = 0.5;

		var x = ( 1 + r * Math.cos( q * t ) ) * Math.cos( p * t );
		var y = ( 1 + r * Math.cos( q * t ) ) * Math.sin( p * t );
		var z = r * Math.sin( q * t );

		return new THREE.Vector3( x, y, z ).multiplyScalar( radius );

	};

	var segments = segmentsT;
	var radiusSegments = segmentsR;
	var extrudePath = new TorusKnotCurve();

	THREE.ParametricGeometries.TubeGeometry.call( this, extrudePath, segments, tube, radiusSegments, true, false );

};

THREE.ParametricGeometries.TorusKnotGeometry.prototype = Object.create( THREE.Geometry.prototype );
THREE.ParametricGeometries.TorusKnotGeometry.prototype.constructor = THREE.ParametricGeometries.TorusKnotGeometry;


 /*********************************************
  *
  * Parametric Replacement for SphereGeometry
  *
  *********************************************/
THREE.ParametricGeometries.SphereGeometry = function( size, u, v ) {

	function sphere( u, v ) {

		u *= Math.PI;
		v *= 2 * Math.PI;

		var x = size * Math.sin( u ) * Math.cos( v );
		var y = size * Math.sin( u ) * Math.sin( v );
		var z = size * Math.cos( u );


		return new THREE.Vector3( x, y, z );

	}

	THREE.ParametricGeometry.call( this, sphere, u, v, ! true );

};

THREE.ParametricGeometries.SphereGeometry.prototype = Object.create( THREE.Geometry.prototype );
THREE.ParametricGeometries.SphereGeometry.prototype.constructor = THREE.ParametricGeometries.SphereGeometry;


 /*********************************************
  *
  * Parametric Replacement for PlaneGeometry
  *
  *********************************************/

THREE.ParametricGeometries.PlaneGeometry = function( width, depth, segmentsWidth, segmentsDepth ) {

	function plane( u, v ) {

		var x = u * width;
		var y = 0;
		var z = v * depth;

		return new THREE.Vector3( x, y, z );

	}

	THREE.ParametricGeometry.call( this, plane, segmentsWidth, segmentsDepth );

};

THREE.ParametricGeometries.PlaneGeometry.prototype = Object.create( THREE.Geometry.prototype );
THREE.ParametricGeometries.PlaneGeometry.prototype.constructor = THREE.ParametricGeometries.PlaneGeometry;