removed unused libraries

2024-11-04 21:53:25 +01:00 · 2015-05-01 11:17:41 +02:00 · 2015-05-01 11:17:41 +02:00 · e17279f7c4
commit e17279f7c4
parent d7dfdb62d9
5 changed files with 4 additions and 2928 deletions
--- a/doodle.html
+++ b/doodle.html
@ -4,7 +4,6 @@
 <title>Doedel Drie Dee</title>
 <!--<script src="http://code.jquery.com/jquery-1.11.0.min.js"></script>-->
 <script src="library/jquery.js"></script>
 <script src="library/cal.js"></script>
 <script src="library/three.js"></script>
 <script src="src/utils.js"></script>
--- a/library/cal.js
+++ b/library/cal.js
--- a/library/csg.js
+++ b/library/csg.js
@ -1,595 +0,0 @@
 // Constructive Solid Geometry (CSG) is a modeling technique that uses Boolean
 // operations like union and intersection to combine 3D solids. This library
 // implements CSG operations on meshes elegantly and concisely using BSP trees,
 // and is meant to serve as an easily understandable implementation of the
 // algorithm. All edge cases involving overlapping coplanar polygons in both
 // solids are correctly handled.
 // 
 // Example usage:
 // 
 //     var cube = CSG.cube();
 //     var sphere = CSG.sphere({ radius: 1.3 });
 //     var polygons = cube.subtract(sphere).toPolygons();
 // 
 // ## Implementation Details
 // 
 // All CSG operations are implemented in terms of two functions, `clipTo()` and
 // `invert()`, which remove parts of a BSP tree inside another BSP tree and swap
 // solid and empty space, respectively. To find the union of `a` and `b`, we
 // want to remove everything in `a` inside `b` and everything in `b` inside `a`,
 // then combine polygons from `a` and `b` into one solid:
 // 
 //     a.clipTo(b);
 //     b.clipTo(a);
 //     a.build(b.allPolygons());
 // 
 // The only tricky part is handling overlapping coplanar polygons in both trees.
 // The code above keeps both copies, but we need to keep them in one tree and
 // remove them in the other tree. To remove them from `b` we can clip the
 // inverse of `b` against `a`. The code for union now looks like this:
 // 
 //     a.clipTo(b);
 //     b.clipTo(a);
 //     b.invert();
 //     b.clipTo(a);
 //     b.invert();
 //     a.build(b.allPolygons());
 // 
 // Subtraction and intersection naturally follow from set operations. If
 // union is `A | B`, subtraction is `A - B = ~(~A | B)` and intersection is
 // `A & B = ~(~A | ~B)` where `~` is the complement operator.
 // 
 // ## License
 // 
 // Copyright (c) 2011 Evan Wallace (http://madebyevan.com/), under the MIT license.
 // # class CSG
 // Holds a binary space partition tree representing a 3D solid. Two solids can
 // be combined using the `union()`, `subtract()`, and `intersect()` methods.
 CSG = function() {
  this.polygons = [];
 };
 // Construct a CSG solid from a list of `CSG.Polygon` instances.
 CSG.fromPolygons = function(polygons) {
  var csg = new CSG();
  csg.polygons = polygons;
  return csg;
 };
 CSG.prototype = {
  clone: function() {
    var csg = new CSG();
    csg.polygons = this.polygons.map(function(p) { return p.clone(); });
    return csg;
  },
  toPolygons: function() {
    return this.polygons;
  },
  // Return a new CSG solid representing space in either this solid or in the
  // solid `csg`. Neither this solid nor the solid `csg` are modified.
  // 
  //     A.union(B)
  // 
  //     +-------+            +-------+
  //     |       |            |       |
  //     |   A   |            |       |
  //     |    +--+----+   =   |       +----+
  //     +----+--+    |       +----+       |
  //          |   B   |            |       |
  //          |       |            |       |
  //          +-------+            +-------+
  // 
  union: function(csg) {
    var a = new CSG.Node(this.clone().polygons);
    var b = new CSG.Node(csg.clone().polygons);
    a.clipTo(b);
    b.clipTo(a);
    b.invert();
    b.clipTo(a);
    b.invert();
    a.build(b.allPolygons());
    return CSG.fromPolygons(a.allPolygons());
  },
  // Return a new CSG solid representing space in this solid but not in the
  // solid `csg`. Neither this solid nor the solid `csg` are modified.
  // 
  //     A.subtract(B)
  // 
  //     +-------+            +-------+
  //     |       |            |       |
  //     |   A   |            |       |
  //     |    +--+----+   =   |    +--+
  //     +----+--+    |       +----+
  //          |   B   |
  //          |       |
  //          +-------+
  // 
  subtract: function(csg) {
    var a = new CSG.Node(this.clone().polygons);
    var b = new CSG.Node(csg.clone().polygons);
    a.invert();
    a.clipTo(b);
    b.clipTo(a);
    b.invert();
    b.clipTo(a);
    b.invert();
    a.build(b.allPolygons());
    a.invert();
    return CSG.fromPolygons(a.allPolygons());
  },
  // Return a new CSG solid representing space both this solid and in the
  // solid `csg`. Neither this solid nor the solid `csg` are modified.
  // 
  //     A.intersect(B)
  // 
  //     +-------+
  //     |       |
  //     |   A   |
  //     |    +--+----+   =   +--+
  //     +----+--+    |       +--+
  //          |   B   |
  //          |       |
  //          +-------+
  // 
  intersect: function(csg) {
    var a = new CSG.Node(this.clone().polygons);
    var b = new CSG.Node(csg.clone().polygons);
    a.invert();
    b.clipTo(a);
    b.invert();
    a.clipTo(b);
    b.clipTo(a);
    a.build(b.allPolygons());
    a.invert();
    return CSG.fromPolygons(a.allPolygons());
  },
  // Return a new CSG solid with solid and empty space switched. This solid is
  // not modified.
  inverse: function() {
    var csg = this.clone();
    csg.polygons.map(function(p) { p.flip(); });
    return csg;
  }
 };
 // Construct an axis-aligned solid cuboid. Optional parameters are `center` and
 // `radius`, which default to `[0, 0, 0]` and `[1, 1, 1]`. The radius can be
 // specified using a single number or a list of three numbers, one for each axis.
 // 
 // Example code:
 // 
 //     var cube = CSG.cube({
 //       center: [0, 0, 0],
 //       radius: 1
 //     });
 CSG.cube = function(options) {
  options = options || {};
  var c = new CSG.Vector(options.center || [0, 0, 0]);
  var r = !options.radius ? [1, 1, 1] : options.radius.length ?
           options.radius : [options.radius, options.radius, options.radius];
  return CSG.fromPolygons([
    [[0, 4, 6, 2], [-1, 0, 0]],
    [[1, 3, 7, 5], [+1, 0, 0]],
    [[0, 1, 5, 4], [0, -1, 0]],
    [[2, 6, 7, 3], [0, +1, 0]],
    [[0, 2, 3, 1], [0, 0, -1]],
    [[4, 5, 7, 6], [0, 0, +1]]
  ].map(function(info) {
    return new CSG.Polygon(info[0].map(function(i) {
      var pos = new CSG.Vector(
        c.x + r[0] * (2 * !!(i & 1) - 1),
        c.y + r[1] * (2 * !!(i & 2) - 1),
        c.z + r[2] * (2 * !!(i & 4) - 1)
      );
      return new CSG.Vertex(pos, new CSG.Vector(info[1]));
    }));
  }));
 };
 // Construct a solid sphere. Optional parameters are `center`, `radius`,
 // `slices`, and `stacks`, which default to `[0, 0, 0]`, `1`, `16`, and `8`.
 // The `slices` and `stacks` parameters control the tessellation along the
 // longitude and latitude directions.
 // 
 // Example usage:
 // 
 //     var sphere = CSG.sphere({
 //       center: [0, 0, 0],
 //       radius: 1,
 //       slices: 16,
 //       stacks: 8
 //     });
 CSG.sphere = function(options) {
  options = options || {};
  var c = new CSG.Vector(options.center || [0, 0, 0]);
  var r = options.radius || 1;
  var slices = options.slices || 16;
  var stacks = options.stacks || 8;
  var polygons = [], vertices;
  function vertex(theta, phi) {
    theta *= Math.PI * 2;
    phi *= Math.PI;
    var dir = new CSG.Vector(
      Math.cos(theta) * Math.sin(phi),
      Math.cos(phi),
      Math.sin(theta) * Math.sin(phi)
    );
    vertices.push(new CSG.Vertex(c.plus(dir.times(r)), dir));
  }
  for (var i = 0; i < slices; i++) {
    for (var j = 0; j < stacks; j++) {
      vertices = [];
      vertex(i / slices, j / stacks);
      if (j > 0) vertex((i + 1) / slices, j / stacks);
      if (j < stacks - 1) vertex((i + 1) / slices, (j + 1) / stacks);
      vertex(i / slices, (j + 1) / stacks);
      polygons.push(new CSG.Polygon(vertices));
    }
  }
  return CSG.fromPolygons(polygons);
 };
 // Construct a solid cylinder. Optional parameters are `start`, `end`,
 // `radius`, and `slices`, which default to `[0, -1, 0]`, `[0, 1, 0]`, `1`, and
 // `16`. The `slices` parameter controls the tessellation.
 // 
 // Example usage:
 // 
 //     var cylinder = CSG.cylinder({
 //       start: [0, -1, 0],
 //       end: [0, 1, 0],
 //       radius: 1,
 //       slices: 16
 //     });
 CSG.cylinder = function(options) {
  options = options || {};
  var s = new CSG.Vector(options.start || [0, -1, 0]);
  var e = new CSG.Vector(options.end || [0, 1, 0]);
  var ray = e.minus(s);
  var r = options.radius || 1;
  var slices = options.slices || 16;
  var axisZ = ray.unit(), isY = (Math.abs(axisZ.y) > 0.5);
  var axisX = new CSG.Vector(isY, !isY, 0).cross(axisZ).unit();
  var axisY = axisX.cross(axisZ).unit();
  var start = new CSG.Vertex(s, axisZ.negated());
  var end = new CSG.Vertex(e, axisZ.unit());
  var polygons = [];
  function point(stack, slice, normalBlend) {
    var angle = slice * Math.PI * 2;
    var out = axisX.times(Math.cos(angle)).plus(axisY.times(Math.sin(angle)));
    var pos = s.plus(ray.times(stack)).plus(out.times(r));
    var normal = out.times(1 - Math.abs(normalBlend)).plus(axisZ.times(normalBlend));
    return new CSG.Vertex(pos, normal);
  }
  for (var i = 0; i < slices; i++) {
    var t0 = i / slices, t1 = (i + 1) / slices;
    polygons.push(new CSG.Polygon([start, point(0, t0, -1), point(0, t1, -1)]));
    polygons.push(new CSG.Polygon([point(0, t1, 0), point(0, t0, 0), point(1, t0, 0), point(1, t1, 0)]));
    polygons.push(new CSG.Polygon([end, point(1, t1, 1), point(1, t0, 1)]));
  }
  return CSG.fromPolygons(polygons);
 };
 // # class Vector
 // Represents a 3D vector.
 // 
 // Example usage:
 // 
 //     new CSG.Vector(1, 2, 3);
 //     new CSG.Vector([1, 2, 3]);
 //     new CSG.Vector({ x: 1, y: 2, z: 3 });
 CSG.Vector = function(x, y, z) {
  if (arguments.length == 3) {
    this.x = x;
    this.y = y;
    this.z = z;
  } else if ('x' in x) {
    this.x = x.x;
    this.y = x.y;
    this.z = x.z;
  } else {
    this.x = x[0];
    this.y = x[1];
    this.z = x[2];
  }
 };
 CSG.Vector.prototype = {
  clone: function() {
    return new CSG.Vector(this.x, this.y, this.z);
  },
  negated: function() {
    return new CSG.Vector(-this.x, -this.y, -this.z);
  },
  plus: function(a) {
    return new CSG.Vector(this.x + a.x, this.y + a.y, this.z + a.z);
  },
  minus: function(a) {
    return new CSG.Vector(this.x - a.x, this.y - a.y, this.z - a.z);
  },
  times: function(a) {
    return new CSG.Vector(this.x * a, this.y * a, this.z * a);
  },
  dividedBy: function(a) {
    return new CSG.Vector(this.x / a, this.y / a, this.z / a);
  },
  dot: function(a) {
    return this.x * a.x + this.y * a.y + this.z * a.z;
  },
  lerp: function(a, t) {
    return this.plus(a.minus(this).times(t));
  },
  length: function() {
    return Math.sqrt(this.dot(this));
  },
  unit: function() {
    return this.dividedBy(this.length());
  },
  cross: function(a) {
    return new CSG.Vector(
      this.y * a.z - this.z * a.y,
      this.z * a.x - this.x * a.z,
      this.x * a.y - this.y * a.x
    );
  }
 };
 // # class Vertex
 // Represents a vertex of a polygon. Use your own vertex class instead of this
 // one to provide additional features like texture coordinates and vertex
 // colors. Custom vertex classes need to provide a `pos` property and `clone()`,
 // `flip()`, and `interpolate()` methods that behave analogous to the ones
 // defined by `CSG.Vertex`. This class provides `normal` so convenience
 // functions like `CSG.sphere()` can return a smooth vertex normal, but `normal`
 // is not used anywhere else.
 CSG.Vertex = function(pos, normal) {
  this.pos = new CSG.Vector(pos);
  this.normal = new CSG.Vector(normal);
 };
 CSG.Vertex.prototype = {
  clone: function() {
    return new CSG.Vertex(this.pos.clone(), this.normal.clone());
  },
  // Invert all orientation-specific data (e.g. vertex normal). Called when the
  // orientation of a polygon is flipped.
  flip: function() {
    this.normal = this.normal.negated();
  },
  // Create a new vertex between this vertex and `other` by linearly
  // interpolating all properties using a parameter of `t`. Subclasses should
  // override this to interpolate additional properties.
  interpolate: function(other, t) {
    return new CSG.Vertex(
      this.pos.lerp(other.pos, t),
      this.normal.lerp(other.normal, t)
    );
  }
 };
 // # class Plane
 // Represents a plane in 3D space.
 CSG.Plane = function(normal, w) {
  this.normal = normal;
  this.w = w;
 };
 // `CSG.Plane.EPSILON` is the tolerance used by `splitPolygon()` to decide if a
 // point is on the plane.
 CSG.Plane.EPSILON = 1e-5;
 CSG.Plane.fromPoints = function(a, b, c) {
  var n = b.minus(a).cross(c.minus(a)).unit();
  return new CSG.Plane(n, n.dot(a));
 };
 CSG.Plane.prototype = {
  clone: function() {
    return new CSG.Plane(this.normal.clone(), this.w);
  },
  flip: function() {
    this.normal = this.normal.negated();
    this.w = -this.w;
  },
  // Split `polygon` by this plane if needed, then put the polygon or polygon
  // fragments in the appropriate lists. Coplanar polygons go into either
  // `coplanarFront` or `coplanarBack` depending on their orientation with
  // respect to this plane. Polygons in front or in back of this plane go into
  // either `front` or `back`.
  splitPolygon: function(polygon, coplanarFront, coplanarBack, front, back) {
    var COPLANAR = 0;
    var FRONT = 1;
    var BACK = 2;
    var SPANNING = 3;
    // Classify each point as well as the entire polygon into one of the above
    // four classes.
    var polygonType = 0;
    var types = [];
    for (var i = 0; i < polygon.vertices.length; i++) {
      var t = this.normal.dot(polygon.vertices[i].pos) - this.w;
      var type = (t < -CSG.Plane.EPSILON) ? BACK : (t > CSG.Plane.EPSILON) ? FRONT : COPLANAR;
      polygonType |= type;
      types.push(type);
    }
    // Put the polygon in the correct list, splitting it when necessary.
    switch (polygonType) {
      case COPLANAR:
        (this.normal.dot(polygon.plane.normal) > 0 ? coplanarFront : coplanarBack).push(polygon);
        break;
      case FRONT:
        front.push(polygon);
        break;
      case BACK:
        back.push(polygon);
        break;
      case SPANNING:
        var f = [], b = [];
        for (var i = 0; i < polygon.vertices.length; i++) {
          var j = (i + 1) % polygon.vertices.length;
          var ti = types[i], tj = types[j];
          var vi = polygon.vertices[i], vj = polygon.vertices[j];
          if (ti != BACK) f.push(vi);
          if (ti != FRONT) b.push(ti != BACK ? vi.clone() : vi);
          if ((ti | tj) == SPANNING) {
            var t = (this.w - this.normal.dot(vi.pos)) / this.normal.dot(vj.pos.minus(vi.pos));
            var v = vi.interpolate(vj, t);
            f.push(v);
            b.push(v.clone());
          }
        }
        if (f.length >= 3) front.push(new CSG.Polygon(f, polygon.shared));
        if (b.length >= 3) back.push(new CSG.Polygon(b, polygon.shared));
        break;
    }
  }
 };
 // # class Polygon
 // Represents a convex polygon. The vertices used to initialize a polygon must
 // be coplanar and form a convex loop. They do not have to be `CSG.Vertex`
 // instances but they must behave similarly (duck typing can be used for
 // customization).
 // 
 // Each convex polygon has a `shared` property, which is shared between all
 // polygons that are clones of each other or were split from the same polygon.
 // This can be used to define per-polygon properties (such as surface color).
 CSG.Polygon = function(vertices, shared) {
  this.vertices = vertices;
  this.shared = shared;
  this.plane = CSG.Plane.fromPoints(vertices[0].pos, vertices[1].pos, vertices[2].pos);
 };
 CSG.Polygon.prototype = {
  clone: function() {
    var vertices = this.vertices.map(function(v) { return v.clone(); });
    return new CSG.Polygon(vertices, this.shared);
  },
  flip: function() {
    this.vertices.reverse().map(function(v) { v.flip(); });
    this.plane.flip();
  }
 };
 // # class Node
 // Holds a node in a BSP tree. A BSP tree is built from a collection of polygons
 // by picking a polygon to split along. That polygon (and all other coplanar
 // polygons) are added directly to that node and the other polygons are added to
 // the front and/or back subtrees. This is not a leafy BSP tree since there is
 // no distinction between internal and leaf nodes.
 CSG.Node = function(polygons) {
  this.plane = null;
  this.front = null;
  this.back = null;
  this.polygons = [];
  if (polygons) this.build(polygons);
 };
 CSG.Node.prototype = {
  clone: function() {
    var node = new CSG.Node();
    node.plane = this.plane && this.plane.clone();
    node.front = this.front && this.front.clone();
    node.back = this.back && this.back.clone();
    node.polygons = this.polygons.map(function(p) { return p.clone(); });
    return node;
  },
  // Convert solid space to empty space and empty space to solid space.
  invert: function() {
    for (var i = 0; i < this.polygons.length; i++) {
      this.polygons[i].flip();
    }
    this.plane.flip();
    if (this.front) this.front.invert();
    if (this.back) this.back.invert();
    var temp = this.front;
    this.front = this.back;
    this.back = temp;
  },
  // Recursively remove all polygons in `polygons` that are inside this BSP
  // tree.
  clipPolygons: function(polygons) {
    if (!this.plane) return polygons.slice();
    var front = [], back = [];
    for (var i = 0; i < polygons.length; i++) {
      this.plane.splitPolygon(polygons[i], front, back, front, back);
    }
    if (this.front) front = this.front.clipPolygons(front);
    if (this.back) back = this.back.clipPolygons(back);
    else back = [];
    return front.concat(back);
  },
  // Remove all polygons in this BSP tree that are inside the other BSP tree
  // `bsp`.
  clipTo: function(bsp) {
    this.polygons = bsp.clipPolygons(this.polygons);
    if (this.front) this.front.clipTo(bsp);
    if (this.back) this.back.clipTo(bsp);
  },
  // Return a list of all polygons in this BSP tree.
  allPolygons: function() {
    var polygons = this.polygons.slice();
    if (this.front) polygons = polygons.concat(this.front.allPolygons());
    if (this.back) polygons = polygons.concat(this.back.allPolygons());
    return polygons;
  },
  // Build a BSP tree out of `polygons`. When called on an existing tree, the
  // new polygons are filtered down to the bottom of the tree and become new
  // nodes there. Each set of polygons is partitioned using the first polygon
  // (no heuristic is used to pick a good split).
  build: function(polygons) {
    if (!polygons.length) return;
    if (!this.plane) this.plane = polygons[0].plane.clone();
    var front = [], back = [];
    for (var i = 0; i < polygons.length; i++) {
      this.plane.splitPolygon(polygons[i], this.polygons, this.polygons, front, back);
    }
    if (front.length) {
      if (!this.front) this.front = new CSG.Node();
      this.front.build(front);
    }
    if (back.length) {
      if (!this.back) this.back = new CSG.Node();
      this.back.build(back);
    }
  }
 };
--- a/slice_test.html
+++ b/slice_test.html
@ -5,7 +5,6 @@
 <!--<script src="http://code.jquery.com/jquery-1.11.0.min.js"></script>-->
 <script src="library/jquery.js"></script>
 <script src="library/three.js"></script>
 <script src="library/cal.js"></script>
 <script src="library/clipper.js"></script>
 <script src="src/utils.js"></script>
--- a/src/slicer.js
+++ b/src/slicer.js
@ -216,8 +216,6 @@ D3D.Slicer.prototype.slicesToData = function (slices, printer) {
 	for (var layer = 0; layer < slices.length; layer ++) {
 		var slice = slices[layer];
 		var highFillTemplate = this.getFillTemplate(dimensionsZ, wallThickness, (layer % 2 === 0), (layer % 2 === 1));
 		//var outerLayer = ClipperLib.JS.Clean(slice, 1.0);
 		var outerLayer = slice.clone();
 		ClipperLib.JS.ScaleUpPaths(outerLayer, scale);
@ -284,6 +282,10 @@ D3D.Slicer.prototype.slicesToData = function (slices, printer) {
 		fill = fill.concat(lowFillStrokes);
 		//optimize
 		//make as big as bounding box of highfillArea
 		var highFillTemplate = this.getFillTemplate(dimensionsZ, wallThickness, (layer % 2 === 0), (layer % 2 === 1));
 		var clipper = new ClipperLib.Clipper();
 		var highFillStrokes = new ClipperLib.Paths();
 		clipper.AddPaths(highFillTemplate, ClipperLib.PolyType.ptSubject, false);