/* YUI 3.17.2 (build 9c3c78e) Copyright 2014 Yahoo! Inc. All rights reserved. Licensed under the BSD License. http://yuilibrary.com/license/ */ YUI.add('graphics-canvas', function (Y, NAME) { var IMPLEMENTATION = "canvas", SHAPE = "shape", SPLITPATHPATTERN = /[a-z][^a-z]*/ig, SPLITARGSPATTERN = /[\-]?[0-9]*[0-9|\.][0-9]*/g, DOCUMENT = Y.config.doc, Y_LANG = Y.Lang, AttributeLite = Y.AttributeLite, CanvasShape, CanvasPath, CanvasRect, CanvasEllipse, CanvasCircle, CanvasPieSlice, Y_DOM = Y.DOM, Y_Color = Y.Color, PARSE_INT = parseInt, PARSE_FLOAT = parseFloat, IS_NUMBER = Y_LANG.isNumber, RE = RegExp, TORGB = Y_Color.toRGB, TOHEX = Y_Color.toHex, _getClassName = Y.ClassNameManager.getClassName; /** * Canvas implementation of the `Drawing` class. * `CanvasDrawing` is not intended to be used directly. Instead, use the `Drawing` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Drawing` * class will point to the `CanvasDrawing` class. * * @module graphics * @class CanvasDrawing * @constructor */ function CanvasDrawing() { } CanvasDrawing.prototype = { /** * Maps path to methods * * @property _pathSymbolToMethod * @type Object * @private */ _pathSymbolToMethod: { M: "moveTo", m: "relativeMoveTo", L: "lineTo", l: "relativeLineTo", C: "curveTo", c: "relativeCurveTo", Q: "quadraticCurveTo", q: "relativeQuadraticCurveTo", z: "closePath", Z: "closePath" }, /** * Current x position of the drawing. * * @property _currentX * @type Number * @private */ _currentX: 0, /** * Current y position of the drqwing. * * @property _currentY * @type Number * @private */ _currentY: 0, /** * Parses hex color string and alpha value to rgba * * @method _toRGBA * @param {Object} val Color value to parse. Can be hex string, rgb or name. * @param {Number} alpha Numeric value between 0 and 1 representing the alpha level. * @private */ _toRGBA: function(val, alpha) { alpha = (alpha !== undefined) ? alpha : 1; if (!Y_Color.re_RGB.test(val)) { val = TOHEX(val); } if(Y_Color.re_hex.exec(val)) { val = 'rgba(' + [ PARSE_INT(RE.$1, 16), PARSE_INT(RE.$2, 16), PARSE_INT(RE.$3, 16) ].join(',') + ',' + alpha + ')'; } return val; }, /** * Converts color to rgb format * * @method _toRGB * @param val Color value to convert. * @private */ _toRGB: function(val) { return TORGB(val); }, /** * Sets the size of the graphics object. * * @method setSize * @param w {Number} width to set for the instance. * @param h {Number} height to set for the instance. * @private */ setSize: function(w, h) { if(this.get("autoSize")) { if(w > this.node.getAttribute("width")) { this.node.style.width = w + "px"; this.node.setAttribute("width", w); } if(h > this.node.getAttribute("height")) { this.node.style.height = h + "px"; this.node.setAttribute("height", h); } } }, /** * Tracks coordinates. Used to calculate the start point of dashed lines. * * @method _updateCoords * @param {Number} x x-coordinate * @param {Number} y y-coordinate * @private */ _updateCoords: function(x, y) { this._xcoords.push(x); this._ycoords.push(y); this._currentX = x; this._currentY = y; }, /** * Clears the coordinate arrays. Called at the end of a drawing operation. * * @method _clearAndUpdateCoords * @private */ _clearAndUpdateCoords: function() { var x = this._xcoords.pop() || 0, y = this._ycoords.pop() || 0; this._updateCoords(x, y); }, /** * Moves the shape's dom node. * * @method _updateNodePosition * @private */ _updateNodePosition: function() { var node = this.get("node"), x = this.get("x"), y = this.get("y"); node.style.position = "absolute"; node.style.left = (x + this._left) + "px"; node.style.top = (y + this._top) + "px"; }, /** * Queues up a method to be executed when a shape redraws. * * @method _updateDrawingQueue * @param {Array} val An array containing data that can be parsed into a method and arguments. The value at zero-index * of the array is a string reference of the drawing method that will be called. All subsequent indices are argument for * that method. For example, `lineTo(10, 100)` would be structured as: * `["lineTo", 10, 100]`. * @private */ _updateDrawingQueue: function(val) { this._methods.push(val); }, /** * Draws a line segment from the current drawing position to the specified x and y coordinates. * * @method lineTo * @param {Number} point1 x-coordinate for the end point. * @param {Number} point2 y-coordinate for the end point. * @chainable */ lineTo: function() { this._lineTo.apply(this, [Y.Array(arguments), false]); return this; }, /** * Draws a line segment from the current drawing position to the relative x and y coordinates. * * @method relativeLineTo * @param {Number} point1 x-coordinate for the end point. * @param {Number} point2 y-coordinate for the end point. * @chainable */ relativeLineTo: function() { this._lineTo.apply(this, [Y.Array(arguments), true]); return this; }, /** * Implements lineTo methods. * * @method _lineTo * @param {Array} args The arguments to be used. * @param {Boolean} relative Indicates whether or not to use relative coordinates. * @private */ _lineTo: function(args, relative) { var point1 = args[0], i, len, x, y, wt = this._stroke && this._strokeWeight ? this._strokeWeight : 0, relativeX = relative ? parseFloat(this._currentX) : 0, relativeY = relative ? parseFloat(this._currentY) : 0; if(!this._lineToMethods) { this._lineToMethods = []; } len = args.length - 1; if (typeof point1 === 'string' || typeof point1 === 'number') { for (i = 0; i < len; i = i + 2) { x = parseFloat(args[i]); y = parseFloat(args[i + 1]); x = x + relativeX; y = y + relativeY; this._updateDrawingQueue(["lineTo", x, y]); this._trackSize(x - wt, y - wt); this._trackSize(x + wt, y + wt); this._updateCoords(x, y); } } else { for (i = 0; i < len; i = i + 1) { x = parseFloat(args[i][0]); y = parseFloat(args[i][1]); this._updateDrawingQueue(["lineTo", x, y]); this._lineToMethods[this._lineToMethods.length] = this._methods[this._methods.length - 1]; this._trackSize(x - wt, y - wt); this._trackSize(x + wt, y + wt); this._updateCoords(x, y); } } this._drawingComplete = false; return this; }, /** * Moves the current drawing position to specified x and y coordinates. * * @method moveTo * @param {Number} x x-coordinate for the end point. * @param {Number} y y-coordinate for the end point. * @chainable */ moveTo: function() { this._moveTo.apply(this, [Y.Array(arguments), false]); return this; }, /** * Moves the current drawing position relative to specified x and y coordinates. * * @method relativeMoveTo * @param {Number} x x-coordinate for the end point. * @param {Number} y y-coordinate for the end point. * @chainable */ relativeMoveTo: function() { this._moveTo.apply(this, [Y.Array(arguments), true]); return this; }, /** * Implements moveTo methods. * * @method _moveTo * @param {Array} args The arguments to be used. * @param {Boolean} relative Indicates whether or not to use relative coordinates. * @private */ _moveTo: function(args, relative) { var wt = this._stroke && this._strokeWeight ? this._strokeWeight : 0, relativeX = relative ? parseFloat(this._currentX) : 0, relativeY = relative ? parseFloat(this._currentY) : 0, x = parseFloat(args[0]) + relativeX, y = parseFloat(args[1]) + relativeY; this._updateDrawingQueue(["moveTo", x, y]); this._trackSize(x - wt, y - wt); this._trackSize(x + wt, y + wt); this._updateCoords(x, y); this._drawingComplete = false; return this; }, /** * Draws a bezier curve. * * @method curveTo * @param {Number} cp1x x-coordinate for the first control point. * @param {Number} cp1y y-coordinate for the first control point. * @param {Number} cp2x x-coordinate for the second control point. * @param {Number} cp2y y-coordinate for the second control point. * @param {Number} x x-coordinate for the end point. * @param {Number} y y-coordinate for the end point. * @chainable */ curveTo: function() { this._curveTo.apply(this, [Y.Array(arguments), false]); return this; }, /** * Draws a bezier curve relative to the current coordinates. * * @method relativeCurveTo * @param {Number} cp1x x-coordinate for the first control point. * @param {Number} cp1y y-coordinate for the first control point. * @param {Number} cp2x x-coordinate for the second control point. * @param {Number} cp2y y-coordinate for the second control point. * @param {Number} x x-coordinate for the end point. * @param {Number} y y-coordinate for the end point. * @chainable */ relativeCurveTo: function() { this._curveTo.apply(this, [Y.Array(arguments), true]); return this; }, /** * Implements curveTo methods. * * @method _curveTo * @param {Array} args The arguments to be used. * @param {Boolean} relative Indicates whether or not to use relative coordinates. * @private */ _curveTo: function(args, relative) { var w, h, cp1x, cp1y, cp2x, cp2y, x, y, pts, right, left, bottom, top, i, len, relativeX = relative ? parseFloat(this._currentX) : 0, relativeY = relative ? parseFloat(this._currentY) : 0; len = args.length - 5; for(i = 0; i < len; i = i + 6) { cp1x = parseFloat(args[i]) + relativeX; cp1y = parseFloat(args[i + 1]) + relativeY; cp2x = parseFloat(args[i + 2]) + relativeX; cp2y = parseFloat(args[i + 3]) + relativeY; x = parseFloat(args[i + 4]) + relativeX; y = parseFloat(args[i + 5]) + relativeY; this._updateDrawingQueue(["bezierCurveTo", cp1x, cp1y, cp2x, cp2y, x, y]); this._drawingComplete = false; right = Math.max(x, Math.max(cp1x, cp2x)); bottom = Math.max(y, Math.max(cp1y, cp2y)); left = Math.min(x, Math.min(cp1x, cp2x)); top = Math.min(y, Math.min(cp1y, cp2y)); w = Math.abs(right - left); h = Math.abs(bottom - top); pts = [[this._currentX, this._currentY] , [cp1x, cp1y], [cp2x, cp2y], [x, y]]; this._setCurveBoundingBox(pts, w, h); this._currentX = x; this._currentY = y; } }, /** * Draws a quadratic bezier curve. * * @method quadraticCurveTo * @param {Number} cpx x-coordinate for the control point. * @param {Number} cpy y-coordinate for the control point. * @param {Number} x x-coordinate for the end point. * @param {Number} y y-coordinate for the end point. * @chainable */ quadraticCurveTo: function() { this._quadraticCurveTo.apply(this, [Y.Array(arguments), false]); return this; }, /** * Draws a quadratic bezier curve relative to the current position. * * @method relativeQuadraticCurveTo * @param {Number} cpx x-coordinate for the control point. * @param {Number} cpy y-coordinate for the control point. * @param {Number} x x-coordinate for the end point. * @param {Number} y y-coordinate for the end point. * @chainable */ relativeQuadraticCurveTo: function() { this._quadraticCurveTo.apply(this, [Y.Array(arguments), true]); return this; }, /** * Implements quadraticCurveTo methods. * * @method _quadraticCurveTo * @param {Array} args The arguments to be used. * @param {Boolean} relative Indicates whether or not to use relative coordinates. * @private */ _quadraticCurveTo: function(args, relative) { var cpx, cpy, x, y, w, h, pts, right, left, bottom, top, i, len = args.length - 3, relativeX = relative ? parseFloat(this._currentX) : 0, relativeY = relative ? parseFloat(this._currentY) : 0; for(i = 0; i < len; i = i + 4) { cpx = parseFloat(args[i]) + relativeX; cpy = parseFloat(args[i + 1]) + relativeY; x = parseFloat(args[i + 2]) + relativeX; y = parseFloat(args[i + 3]) + relativeY; this._drawingComplete = false; right = Math.max(x, cpx); bottom = Math.max(y, cpy); left = Math.min(x, cpx); top = Math.min(y, cpy); w = Math.abs(right - left); h = Math.abs(bottom - top); pts = [[this._currentX, this._currentY] , [cpx, cpy], [x, y]]; this._setCurveBoundingBox(pts, w, h); this._updateDrawingQueue(["quadraticCurveTo", cpx, cpy, x, y]); this._updateCoords(x, y); } return this; }, /** * Draws a circle. Used internally by `CanvasCircle` class. * * @method drawCircle * @param {Number} x y-coordinate * @param {Number} y x-coordinate * @param {Number} r radius * @chainable * @protected */ drawCircle: function(x, y, radius) { var startAngle = 0, endAngle = 2 * Math.PI, wt = this._stroke && this._strokeWeight ? this._strokeWeight : 0, circum = radius * 2; circum += wt; this._drawingComplete = false; this._trackSize(x + circum, y + circum); this._trackSize(x - wt, y - wt); this._updateCoords(x, y); this._updateDrawingQueue(["arc", x + radius, y + radius, radius, startAngle, endAngle, false]); return this; }, /** * Draws a diamond. * * @method drawDiamond * @param {Number} x y-coordinate * @param {Number} y x-coordinate * @param {Number} width width * @param {Number} height height * @chainable * @protected */ drawDiamond: function(x, y, width, height) { var midWidth = width * 0.5, midHeight = height * 0.5; this.moveTo(x + midWidth, y); this.lineTo(x + width, y + midHeight); this.lineTo(x + midWidth, y + height); this.lineTo(x, y + midHeight); this.lineTo(x + midWidth, y); return this; }, /** * Draws an ellipse. Used internally by `CanvasEllipse` class. * * @method drawEllipse * @param {Number} x x-coordinate * @param {Number} y y-coordinate * @param {Number} w width * @param {Number} h height * @chainable * @protected */ drawEllipse: function(x, y, w, h) { var l = 8, theta = -(45/180) * Math.PI, angle = 0, angleMid, radius = w/2, yRadius = h/2, i, centerX = x + radius, centerY = y + yRadius, ax, ay, bx, by, cx, cy, wt = this._stroke && this._strokeWeight ? this._strokeWeight : 0; ax = centerX + Math.cos(0) * radius; ay = centerY + Math.sin(0) * yRadius; this.moveTo(ax, ay); for(i = 0; i < l; i++) { angle += theta; angleMid = angle - (theta / 2); bx = centerX + Math.cos(angle) * radius; by = centerY + Math.sin(angle) * yRadius; cx = centerX + Math.cos(angleMid) * (radius / Math.cos(theta / 2)); cy = centerY + Math.sin(angleMid) * (yRadius / Math.cos(theta / 2)); this._updateDrawingQueue(["quadraticCurveTo", cx, cy, bx, by]); } this._trackSize(x + w + wt, y + h + wt); this._trackSize(x - wt, y - wt); this._updateCoords(x, y); return this; }, /** * Draws a rectangle. * * @method drawRect * @param {Number} x x-coordinate * @param {Number} y y-coordinate * @param {Number} w width * @param {Number} h height * @chainable */ drawRect: function(x, y, w, h) { this._drawingComplete = false; this.moveTo(x, y); this.lineTo(x + w, y); this.lineTo(x + w, y + h); this.lineTo(x, y + h); this.lineTo(x, y); return this; }, /** * Draws a rectangle with rounded corners. * * @method drawRect * @param {Number} x x-coordinate * @param {Number} y y-coordinate * @param {Number} w width * @param {Number} h height * @param {Number} ew width of the ellipse used to draw the rounded corners * @param {Number} eh height of the ellipse used to draw the rounded corners * @chainable */ drawRoundRect: function(x, y, w, h, ew, eh) { this._drawingComplete = false; this.moveTo( x, y + eh); this.lineTo(x, y + h - eh); this.quadraticCurveTo(x, y + h, x + ew, y + h); this.lineTo(x + w - ew, y + h); this.quadraticCurveTo(x + w, y + h, x + w, y + h - eh); this.lineTo(x + w, y + eh); this.quadraticCurveTo(x + w, y, x + w - ew, y); this.lineTo(x + ew, y); this.quadraticCurveTo(x, y, x, y + eh); return this; }, /** * Draws a wedge. * * @method drawWedge * @param {Number} x x-coordinate of the wedge's center point * @param {Number} y y-coordinate of the wedge's center point * @param {Number} startAngle starting angle in degrees * @param {Number} arc sweep of the wedge. Negative values draw clockwise. * @param {Number} radius radius of wedge. If [optional] yRadius is defined, then radius is the x radius. * @param {Number} yRadius [optional] y radius for wedge. * @chainable * @private */ drawWedge: function(x, y, startAngle, arc, radius, yRadius) { var wt = this._stroke && this._strokeWeight ? this._strokeWeight : 0, segs, segAngle, theta, angle, angleMid, ax, ay, bx, by, cx, cy, i = 0; yRadius = yRadius || radius; this._drawingComplete = false; // move to x,y position this._updateDrawingQueue(["moveTo", x, y]); yRadius = yRadius || radius; // limit sweep to reasonable numbers if(Math.abs(arc) > 360) { arc = 360; } // First we calculate how many segments are needed // for a smooth arc. segs = Math.ceil(Math.abs(arc) / 45); // Now calculate the sweep of each segment. segAngle = arc / segs; // The math requires radians rather than degrees. To convert from degrees // use the formula (degrees/180)*Math.PI to get radians. theta = -(segAngle / 180) * Math.PI; // convert angle startAngle to radians angle = (startAngle / 180) * Math.PI; // draw the curve in segments no larger than 45 degrees. if(segs > 0) { // draw a line from the center to the start of the curve ax = x + Math.cos(startAngle / 180 * Math.PI) * radius; ay = y + Math.sin(startAngle / 180 * Math.PI) * yRadius; this.lineTo(ax, ay); // Loop for drawing curve segments for(i = 0; i < segs; ++i) { angle += theta; angleMid = angle - (theta / 2); bx = x + Math.cos(angle) * radius; by = y + Math.sin(angle) * yRadius; cx = x + Math.cos(angleMid) * (radius / Math.cos(theta / 2)); cy = y + Math.sin(angleMid) * (yRadius / Math.cos(theta / 2)); this._updateDrawingQueue(["quadraticCurveTo", cx, cy, bx, by]); } // close the wedge by drawing a line to the center this._updateDrawingQueue(["lineTo", x, y]); } this._trackSize(-wt , -wt); this._trackSize((radius * 2) + wt, (radius * 2) + wt); return this; }, /** * Completes a drawing operation. * * @method end * @chainable */ end: function() { this._closePath(); return this; }, /** * Ends a fill and stroke * * @method closePath * @chainable */ closePath: function() { this._updateDrawingQueue(["closePath"]); this._updateDrawingQueue(["beginPath"]); return this; }, /** * Clears the graphics object. * * @method clear * @chainable */ clear: function() { this._initProps(); if(this.node) { this._context.clearRect(0, 0, this.node.width, this.node.height); } return this; }, /** * Returns a linear gradient fill * * @method _getLinearGradient * @return CanvasGradient * @private */ _getLinearGradient: function() { var isNumber = Y.Lang.isNumber, fill = this.get("fill"), stops = fill.stops, opacity, color, stop, i, len = stops.length, gradient, x = 0, y = 0, w = this.get("width"), h = this.get("height"), r = fill.rotation || 0, x1, x2, y1, y2, cx = x + w/2, cy = y + h/2, offset, radCon = Math.PI/180, tanRadians = parseFloat(parseFloat(Math.tan(r * radCon)).toFixed(8)); if(Math.abs(tanRadians) * w/2 >= h/2) { if(r < 180) { y1 = y; y2 = y + h; } else { y1 = y + h; y2 = y; } x1 = cx - ((cy - y1)/tanRadians); x2 = cx - ((cy - y2)/tanRadians); } else { if(r > 90 && r < 270) { x1 = x + w; x2 = x; } else { x1 = x; x2 = x + w; } y1 = ((tanRadians * (cx - x1)) - cy) * -1; y2 = ((tanRadians * (cx - x2)) - cy) * -1; } gradient = this._context.createLinearGradient(x1, y1, x2, y2); for(i = 0; i < len; ++i) { stop = stops[i]; opacity = stop.opacity; color = stop.color; offset = stop.offset; if(isNumber(opacity)) { opacity = Math.max(0, Math.min(1, opacity)); color = this._toRGBA(color, opacity); } else { color = TORGB(color); } offset = stop.offset || i/(len - 1); gradient.addColorStop(offset, color); } return gradient; }, /** * Returns a radial gradient fill * * @method _getRadialGradient * @return CanvasGradient * @private */ _getRadialGradient: function() { var isNumber = Y.Lang.isNumber, fill = this.get("fill"), r = fill.r, fx = fill.fx, fy = fill.fy, stops = fill.stops, opacity, color, stop, i, len = stops.length, gradient, x = 0, y = 0, w = this.get("width"), h = this.get("height"), x1, x2, y1, y2, r2, xc, yc, xn, yn, d, offset, ratio, stopMultiplier; xc = x + w/2; yc = y + h/2; x1 = w * fx; y1 = h * fy; x2 = x + w/2; y2 = y + h/2; r2 = w * r; d = Math.sqrt( Math.pow(Math.abs(xc - x1), 2) + Math.pow(Math.abs(yc - y1), 2) ); if(d >= r2) { ratio = d/r2; //hack. gradient won't show if it is exactly on the edge of the arc if(ratio === 1) { ratio = 1.01; } xn = (x1 - xc)/ratio; yn = (y1 - yc)/ratio; xn = xn > 0 ? Math.floor(xn) : Math.ceil(xn); yn = yn > 0 ? Math.floor(yn) : Math.ceil(yn); x1 = xc + xn; y1 = yc + yn; } //If the gradient radius is greater than the circle's, adjusting the radius stretches the gradient properly. //If the gradient radius is less than the circle's, adjusting the radius of the gradient will not work. //Instead, adjust the color stops to reflect the smaller radius. if(r >= 0.5) { gradient = this._context.createRadialGradient(x1, y1, r, x2, y2, r * w); stopMultiplier = 1; } else { gradient = this._context.createRadialGradient(x1, y1, r, x2, y2, w/2); stopMultiplier = r * 2; } for(i = 0; i < len; ++i) { stop = stops[i]; opacity = stop.opacity; color = stop.color; offset = stop.offset; if(isNumber(opacity)) { opacity = Math.max(0, Math.min(1, opacity)); color = this._toRGBA(color, opacity); } else { color = TORGB(color); } offset = stop.offset || i/(len - 1); offset *= stopMultiplier; if(offset <= 1) { gradient.addColorStop(offset, color); } } return gradient; }, /** * Clears all values * * @method _initProps * @private */ _initProps: function() { this._methods = []; this._lineToMethods = []; this._xcoords = [0]; this._ycoords = [0]; this._width = 0; this._height = 0; this._left = 0; this._top = 0; this._right = 0; this._bottom = 0; this._currentX = 0; this._currentY = 0; }, /** * Indicates a drawing has completed. * * @property _drawingComplete * @type Boolean * @private */ _drawingComplete: false, /** * Creates canvas element * * @method _createGraphic * @return HTMLCanvasElement * @private */ _createGraphic: function() { var graphic = Y.config.doc.createElement('canvas'); return graphic; }, /** * Returns the points on a curve * * @method getBezierData * @param Array points Array containing the begin, end and control points of a curve. * @param Number t The value for incrementing the next set of points. * @return Array * @private */ getBezierData: function(points, t) { var n = points.length, tmp = [], i, j; for (i = 0; i < n; ++i){ tmp[i] = [points[i][0], points[i][1]]; // save input } for (j = 1; j < n; ++j) { for (i = 0; i < n - j; ++i) { tmp[i][0] = (1 - t) * tmp[i][0] + t * tmp[parseInt(i + 1, 10)][0]; tmp[i][1] = (1 - t) * tmp[i][1] + t * tmp[parseInt(i + 1, 10)][1]; } } return [ tmp[0][0], tmp[0][1] ]; }, /** * Calculates the bounding box for a curve * * @method _setCurveBoundingBox * @param Array pts Array containing points for start, end and control points of a curve. * @param Number w Width used to calculate the number of points to describe the curve. * @param Number h Height used to calculate the number of points to describe the curve. * @private */ _setCurveBoundingBox: function(pts, w, h) { var i = 0, left = this._currentX, right = left, top = this._currentY, bottom = top, len = Math.round(Math.sqrt((w * w) + (h * h))), t = 1/len, wt = this._stroke && this._strokeWeight ? this._strokeWeight : 0, xy; for(i = 0; i < len; ++i) { xy = this.getBezierData(pts, t * i); left = isNaN(left) ? xy[0] : Math.min(xy[0], left); right = isNaN(right) ? xy[0] : Math.max(xy[0], right); top = isNaN(top) ? xy[1] : Math.min(xy[1], top); bottom = isNaN(bottom) ? xy[1] : Math.max(xy[1], bottom); } left = Math.round(left * 10)/10; right = Math.round(right * 10)/10; top = Math.round(top * 10)/10; bottom = Math.round(bottom * 10)/10; this._trackSize(right + wt, bottom + wt); this._trackSize(left - wt, top - wt); }, /** * Updates the size of the graphics object * * @method _trackSize * @param {Number} w width * @param {Number} h height * @private */ _trackSize: function(w, h) { if (w > this._right) { this._right = w; } if(w < this._left) { this._left = w; } if (h < this._top) { this._top = h; } if (h > this._bottom) { this._bottom = h; } this._width = this._right - this._left; this._height = this._bottom - this._top; } }; Y.CanvasDrawing = CanvasDrawing; /** * Canvas implementation of the `Shape` class. * `CanvasShape` is not intended to be used directly. Instead, use the `Shape` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Shape` * class will point to the `CanvasShape` class. * * @module graphics * @class CanvasShape * @constructor */ CanvasShape = function() { this._transforms = []; this.matrix = new Y.Matrix(); CanvasShape.superclass.constructor.apply(this, arguments); }; CanvasShape.NAME = "shape"; Y.extend(CanvasShape, Y.GraphicBase, Y.mix({ /** * Init method, invoked during construction. * Calls `initializer` method. * * @method init * @protected */ init: function() { this.initializer.apply(this, arguments); }, /** * Initializes the shape * * @private * @method _initialize */ initializer: function(cfg) { var host = this, graphic = cfg.graphic, data = this.get("data"); host._initProps(); host.createNode(); host._xcoords = [0]; host._ycoords = [0]; if(graphic) { this._setGraphic(graphic); } if(data) { host._parsePathData(data); } host._updateHandler(); }, /** * Set the Graphic instance for the shape. * * @method _setGraphic * @param {Graphic | Node | HTMLElement | String} render This param is used to determine the graphic instance. If it is a * `Graphic` instance, it will be assigned to the `graphic` attribute. Otherwise, a new Graphic instance will be created * and rendered into the dom element that the render represents. * @private */ _setGraphic: function(render) { var graphic; if(render instanceof Y.CanvasGraphic) { this._graphic = render; } else { graphic = new Y.CanvasGraphic({ render: render }); graphic._appendShape(this); this._graphic = graphic; } }, /** * Add a class name to each node. * * @method addClass * @param {String} className the class name to add to the node's class attribute */ addClass: function(className) { var node = this.get("node"); Y.DOM.addClass(node, className); }, /** * Removes a class name from each node. * * @method removeClass * @param {String} className the class name to remove from the node's class attribute */ removeClass: function(className) { var node = this.get("node"); Y.DOM.removeClass(node, className); }, /** * Gets the current position of the node in page coordinates. * * @method getXY * @return Array The XY position of the shape. */ getXY: function() { var graphic = this.get("graphic"), parentXY = graphic.getXY(), x = this.get("x"), y = this.get("y"); return [parentXY[0] + x, parentXY[1] + y]; }, /** * Set the position of the shape in page coordinates, regardless of how the node is positioned. * * @method setXY * @param {Array} Contains X & Y values for new position (coordinates are page-based) */ setXY: function(xy) { var graphic = this.get("graphic"), parentXY = graphic.getXY(), x = xy[0] - parentXY[0], y = xy[1] - parentXY[1]; this._set("x", x); this._set("y", y); this._updateNodePosition(x, y); }, /** * Determines whether the node is an ancestor of another HTML element in the DOM hierarchy. * * @method contains * @param {CanvasShape | HTMLElement} needle The possible node or descendent * @return Boolean Whether or not this shape is the needle or its ancestor. */ contains: function(needle) { var node = needle instanceof Y.Node ? needle._node : needle; return node === this.node; }, /** * Test if the supplied node matches the supplied selector. * * @method test * @param {String} selector The CSS selector to test against. * @return Boolean Wheter or not the shape matches the selector. */ test: function(selector) { return Y.Selector.test(this.node, selector); }, /** * Compares nodes to determine if they match. * Node instances can be compared to each other and/or HTMLElements. * @method compareTo * @param {HTMLElement | Node} refNode The reference node to compare to the node. * @return {Boolean} True if the nodes match, false if they do not. */ compareTo: function(refNode) { var node = this.node; return node === refNode; }, /** * Value function for fill attribute * * @method _getDefaultFill * @return Object * @private */ _getDefaultFill: function() { return { type: "solid", opacity: 1, cx: 0.5, cy: 0.5, fx: 0.5, fy: 0.5, r: 0.5 }; }, /** * Value function for stroke attribute * * @method _getDefaultStroke * @return Object * @private */ _getDefaultStroke: function() { return { weight: 1, dashstyle: "none", color: "#000", opacity: 1.0 }; }, /** * Left edge of the path * * @property _left * @type Number * @private */ _left: 0, /** * Right edge of the path * * @property _right * @type Number * @private */ _right: 0, /** * Top edge of the path * * @property _top * @type Number * @private */ _top: 0, /** * Bottom edge of the path * * @property _bottom * @type Number * @private */ _bottom: 0, /** * Creates the dom node for the shape. * * @method createNode * @return HTMLElement * @private */ createNode: function() { var host = this, node = Y.config.doc.createElement('canvas'), id = host.get("id"), concat = host._camelCaseConcat, name = host.name; host._context = node.getContext('2d'); node.setAttribute("overflow", "visible"); node.style.overflow = "visible"; if(!host.get("visible")) { node.style.visibility = "hidden"; } node.setAttribute("id", id); id = "#" + id; host.node = node; host.addClass( _getClassName(SHAPE) + " " + _getClassName(concat(IMPLEMENTATION, SHAPE)) + " " + _getClassName(name) + " " + _getClassName(concat(IMPLEMENTATION, name)) ); }, /** * Overrides default `on` method. Checks to see if its a dom interaction event. If so, * return an event attached to the `node` element. If not, return the normal functionality. * * @method on * @param {String} type event type * @param {Object} callback function * @private */ on: function(type, fn) { if(Y.Node.DOM_EVENTS[type]) { return Y.on(type, fn, "#" + this.get("id")); } return Y.on.apply(this, arguments); }, /** * Adds a stroke to the shape node. * * @method _strokeChangeHandler * @param {Object} stroke Properties of the `stroke` attribute. * @private */ _setStrokeProps: function(stroke) { var color, weight, opacity, linejoin, linecap, dashstyle; if(stroke) { color = stroke.color; weight = PARSE_FLOAT(stroke.weight); opacity = PARSE_FLOAT(stroke.opacity); linejoin = stroke.linejoin || "round"; linecap = stroke.linecap || "butt"; dashstyle = stroke.dashstyle; this._miterlimit = null; this._dashstyle = (dashstyle && Y.Lang.isArray(dashstyle) && dashstyle.length > 1) ? dashstyle : null; this._strokeWeight = weight; if (IS_NUMBER(weight) && weight > 0) { this._stroke = 1; } else { this._stroke = 0; } if (IS_NUMBER(opacity)) { this._strokeStyle = this._toRGBA(color, opacity); } else { this._strokeStyle = color; } this._linecap = linecap; if(linejoin === "round" || linejoin === "bevel") { this._linejoin = linejoin; } else { linejoin = parseInt(linejoin, 10); if(IS_NUMBER(linejoin)) { this._miterlimit = Math.max(linejoin, 1); this._linejoin = "miter"; } } } else { this._stroke = 0; } }, /** * Sets the value of an attribute. * * @method set * @param {String|Object} name The name of the attribute. Alternatively, an object of key value pairs can * be passed in to set multiple attributes at once. * @param {Any} value The value to set the attribute to. This value is ignored if an object is received as * the name param. */ set: function() { var host = this; AttributeLite.prototype.set.apply(host, arguments); if(host.initialized) { host._updateHandler(); } }, /** * Adds a fill to the shape node. * * @method _setFillProps * @param {Object} fill Properties of the `fill` attribute. * @private */ _setFillProps: function(fill) { var isNumber = IS_NUMBER, color, opacity, type; if(fill) { color = fill.color; type = fill.type; if(type === "linear" || type === "radial") { this._fillType = type; } else if(color) { opacity = fill.opacity; if (isNumber(opacity)) { opacity = Math.max(0, Math.min(1, opacity)); color = this._toRGBA(color, opacity); } else { color = TORGB(color); } this._fillColor = color; this._fillType = 'solid'; } else { this._fillColor = null; } } else { this._fillType = null; this._fillColor = null; } }, /** * Specifies a 2d translation. * * @method translate * @param {Number} x The value to transate on the x-axis. * @param {Number} y The value to translate on the y-axis. */ translate: function(x, y) { this._translateX += x; this._translateY += y; this._addTransform("translate", arguments); }, /** * Translates the shape along the x-axis. When translating x and y coordinates, * use the `translate` method. * * @method translateX * @param {Number} x The value to translate. */ translateX: function(x) { this._translateX += x; this._addTransform("translateX", arguments); }, /** * Performs a translate on the y-coordinate. When translating x and y coordinates, * use the `translate` method. * * @method translateY * @param {Number} y The value to translate. */ translateY: function(y) { this._translateY += y; this._addTransform("translateY", arguments); }, /** * Skews the shape around the x-axis and y-axis. * * @method skew * @param {Number} x The value to skew on the x-axis. * @param {Number} y The value to skew on the y-axis. */ skew: function() { this._addTransform("skew", arguments); }, /** * Skews the shape around the x-axis. * * @method skewX * @param {Number} x x-coordinate */ skewX: function() { this._addTransform("skewX", arguments); }, /** * Skews the shape around the y-axis. * * @method skewY * @param {Number} y y-coordinate */ skewY: function() { this._addTransform("skewY", arguments); }, /** * Rotates the shape clockwise around it transformOrigin. * * @method rotate * @param {Number} deg The degree of the rotation. */ rotate: function() { this._addTransform("rotate", arguments); }, /** * Specifies a 2d scaling operation. * * @method scale * @param {Number} val */ scale: function() { this._addTransform("scale", arguments); }, /** * Storage for the transform attribute. * * @property _transform * @type String * @private */ _transform: "", /** * Adds a transform to the shape. * * @method _addTransform * @param {String} type The transform being applied. * @param {Array} args The arguments for the transform. * @private */ _addTransform: function(type, args) { args = Y.Array(args); this._transform = Y_LANG.trim(this._transform + " " + type + "(" + args.join(", ") + ")"); args.unshift(type); this._transforms.push(args); if(this.initialized) { this._updateTransform(); } }, /** * Applies all transforms. * * @method _updateTransform * @private */ _updateTransform: function() { var node = this.node, key, transform, transformOrigin = this.get("transformOrigin"), matrix = this.matrix, i, len = this._transforms.length; if(this._transforms && this._transforms.length > 0) { for(i = 0; i < len; ++i) { key = this._transforms[i].shift(); if(key) { matrix[key].apply(matrix, this._transforms[i]); } } transform = matrix.toCSSText(); } this._graphic.addToRedrawQueue(this); transformOrigin = (100 * transformOrigin[0]) + "% " + (100 * transformOrigin[1]) + "%"; Y_DOM.setStyle(node, "transformOrigin", transformOrigin); if(transform) { Y_DOM.setStyle(node, "transform", transform); } this._transforms = []; }, /** * Updates `Shape` based on attribute changes. * * @method _updateHandler * @private */ _updateHandler: function() { this._draw(); this._updateTransform(); }, /** * Updates the shape. * * @method _draw * @private */ _draw: function() { var node = this.node; this.clear(); this._closePath(); node.style.left = this.get("x") + "px"; node.style.top = this.get("y") + "px"; }, /** * Completes a shape or drawing * * @method _closePath * @private */ _closePath: function() { if(!this._methods) { return; } var node = this.get("node"), w = this._right - this._left, h = this._bottom - this._top, context = this._context, methods = [], cachedMethods = this._methods.concat(), i, j, method, args, argsLen, len = 0; this._context.clearRect(0, 0, node.width, node.height); if(this._methods) { len = cachedMethods.length; if(!len || len < 1) { return; } for(i = 0; i < len; ++i) { methods[i] = cachedMethods[i].concat(); args = methods[i]; argsLen = (args[0] === "quadraticCurveTo" || args[0] === "bezierCurveTo") ? args.length : 3; for(j = 1; j < argsLen; ++j) { if(j % 2 === 0) { args[j] = args[j] - this._top; } else { args[j] = args[j] - this._left; } } } node.setAttribute("width", Math.min(w, 2000)); node.setAttribute("height", Math.min(2000, h)); context.beginPath(); for(i = 0; i < len; ++i) { args = methods[i].concat(); if(args && args.length > 0) { method = args.shift(); if(method) { if(method === "closePath") { context.closePath(); this._strokeAndFill(context); } else if(method && method === "lineTo" && this._dashstyle) { args.unshift(this._xcoords[i] - this._left, this._ycoords[i] - this._top); this._drawDashedLine.apply(this, args); } else { context[method].apply(context, args); } } } } this._strokeAndFill(context); this._drawingComplete = true; this._clearAndUpdateCoords(); this._updateNodePosition(); this._methods = cachedMethods; } }, /** * Completes a stroke and/or fill operation on the context. * * @method _strokeAndFill * @param {Context} Reference to the context element of the canvas instance. * @private */ _strokeAndFill: function(context) { if (this._fillType) { if(this._fillType === "linear") { context.fillStyle = this._getLinearGradient(); } else if(this._fillType === "radial") { context.fillStyle = this._getRadialGradient(); } else { context.fillStyle = this._fillColor; } context.closePath(); context.fill(); } if (this._stroke) { if(this._strokeWeight) { context.lineWidth = this._strokeWeight; } context.lineCap = this._linecap; context.lineJoin = this._linejoin; if(this._miterlimit) { context.miterLimit = this._miterlimit; } context.strokeStyle = this._strokeStyle; context.stroke(); } }, /** * Draws a dashed line between two points. * * @method _drawDashedLine * @param {Number} xStart The x position of the start of the line * @param {Number} yStart The y position of the start of the line * @param {Number} xEnd The x position of the end of the line * @param {Number} yEnd The y position of the end of the line * @private */ _drawDashedLine: function(xStart, yStart, xEnd, yEnd) { var context = this._context, dashsize = this._dashstyle[0], gapsize = this._dashstyle[1], segmentLength = dashsize + gapsize, xDelta = xEnd - xStart, yDelta = yEnd - yStart, delta = Math.sqrt(Math.pow(xDelta, 2) + Math.pow(yDelta, 2)), segmentCount = Math.floor(Math.abs(delta / segmentLength)), radians = Math.atan2(yDelta, xDelta), xCurrent = xStart, yCurrent = yStart, i; xDelta = Math.cos(radians) * segmentLength; yDelta = Math.sin(radians) * segmentLength; for(i = 0; i < segmentCount; ++i) { context.moveTo(xCurrent, yCurrent); context.lineTo(xCurrent + Math.cos(radians) * dashsize, yCurrent + Math.sin(radians) * dashsize); xCurrent += xDelta; yCurrent += yDelta; } context.moveTo(xCurrent, yCurrent); delta = Math.sqrt((xEnd - xCurrent) * (xEnd - xCurrent) + (yEnd - yCurrent) * (yEnd - yCurrent)); if(delta > dashsize) { context.lineTo(xCurrent + Math.cos(radians) * dashsize, yCurrent + Math.sin(radians) * dashsize); } else if(delta > 0) { context.lineTo(xCurrent + Math.cos(radians) * delta, yCurrent + Math.sin(radians) * delta); } context.moveTo(xEnd, yEnd); }, /** * Returns the bounds for a shape. * * Calculates the a new bounding box from the original corner coordinates (base on size and position) and the transform matrix. * The calculated bounding box is used by the graphic instance to calculate its viewBox. * * @method getBounds * @return Object */ getBounds: function() { var type = this._type, w = this.get("width"), h = this.get("height"), x = this.get("x"), y = this.get("y"); if(type === "path") { x = x + this._left; y = y + this._top; w = this._right - this._left; h = this._bottom - this._top; } return this._getContentRect(w, h, x, y); }, /** * Calculates the bounding box for the shape. * * @method _getContentRect * @param {Number} w width of the shape * @param {Number} h height of the shape * @param {Number} x x-coordinate of the shape * @param {Number} y y-coordinate of the shape * @private */ _getContentRect: function(w, h, x, y) { var transformOrigin = this.get("transformOrigin"), transformX = transformOrigin[0] * w, transformY = transformOrigin[1] * h, transforms = this.matrix.getTransformArray(this.get("transform")), matrix = new Y.Matrix(), i, len = transforms.length, transform, key, contentRect; if(this._type === "path") { transformX = transformX + x; transformY = transformY + y; } transformX = !isNaN(transformX) ? transformX : 0; transformY = !isNaN(transformY) ? transformY : 0; matrix.translate(transformX, transformY); for(i = 0; i < len; i = i + 1) { transform = transforms[i]; key = transform.shift(); if(key) { matrix[key].apply(matrix, transform); } } matrix.translate(-transformX, -transformY); contentRect = matrix.getContentRect(w, h, x, y); return contentRect; }, /** * Places the shape above all other shapes. * * @method toFront */ toFront: function() { var graphic = this.get("graphic"); if(graphic) { graphic._toFront(this); } }, /** * Places the shape underneath all other shapes. * * @method toFront */ toBack: function() { var graphic = this.get("graphic"); if(graphic) { graphic._toBack(this); } }, /** * Parses path data string and call mapped methods. * * @method _parsePathData * @param {String} val The path data * @private */ _parsePathData: function(val) { var method, methodSymbol, args, commandArray = Y.Lang.trim(val.match(SPLITPATHPATTERN)), i, len, str, symbolToMethod = this._pathSymbolToMethod; if(commandArray) { this.clear(); len = commandArray.length || 0; for(i = 0; i < len; i = i + 1) { str = commandArray[i]; methodSymbol = str.substr(0, 1); args = str.substr(1).match(SPLITARGSPATTERN); method = symbolToMethod[methodSymbol]; if(method) { if(args) { this[method].apply(this, args); } else { this[method].apply(this); } } } this.end(); } }, /** * Destroys the shape instance. * * @method destroy */ destroy: function() { var graphic = this.get("graphic"); if(graphic) { graphic.removeShape(this); } else { this._destroy(); } }, /** * Implementation for shape destruction * * @method destroy * @protected */ _destroy: function() { if(this.node) { Y.Event.purgeElement(this.node, true); if(this.node.parentNode) { this.node.style.visibility = ""; this.node.parentNode.removeChild(this.node); } this._context = null; this.node = null; } } }, Y.CanvasDrawing.prototype)); CanvasShape.ATTRS = { /** * An array of x, y values which indicates the transformOrigin in which to rotate the shape. Valid values range between 0 and 1 representing a * fraction of the shape's corresponding bounding box dimension. The default value is [0.5, 0.5]. * * @config transformOrigin * @type Array */ transformOrigin: { valueFn: function() { return [0.5, 0.5]; } }, /** *

A string containing, in order, transform operations applied to the shape instance. The `transform` string can contain the following values: * *

rotate: Rotates the shape clockwise around it transformOrigin.
translate: Specifies a 2d translation.
skew: Skews the shape around the x-axis and y-axis.
scale: Specifies a 2d scaling operation.
translateX: Translates the shape along the x-axis.
translateY: Translates the shape along the y-axis.
skewX: Skews the shape around the x-axis.
skewY: Skews the shape around the y-axis.
matrix: Specifies a 2D transformation matrix comprised of the specified six values.

*

*

Applying transforms through the transform attribute will reset the transform matrix and apply a new transform. The shape class also contains * corresponding methods for each transform that will apply the transform to the current matrix. The below code illustrates how you might use the * `transform` attribute to instantiate a recangle with a rotation of 45 degrees.

var myRect = new Y.Rect({ type:"rect", width: 50, height: 40, transform: "rotate(45)" }; *

The code below would apply `translate` and `rotate` to an existing shape.

myRect.set("transform", "translate(40, 50) rotate(45)"); * @config transform * @type String */ transform: { setter: function(val) { this.matrix.init(); this._transforms = this.matrix.getTransformArray(val); this._transform = val; return val; }, getter: function() { return this._transform; } }, /** * Dom node for the shape * * @config node * @type HTMLElement * @readOnly */ node: { readOnly: true, getter: function() { return this.node; } }, /** * Unique id for class instance. * * @config id * @type String */ id: { valueFn: function() { return Y.guid(); }, setter: function(val) { var node = this.node; if(node) { node.setAttribute("id", val); } return val; } }, /** * Indicates the width of the shape * * @config width * @type Number */ width: { value: 0 }, /** * Indicates the height of the shape * * @config height * @type Number */ height: { value: 0 }, /** * Indicates the x position of shape. * * @config x * @type Number */ x: { value: 0 }, /** * Indicates the y position of shape. * * @config y * @type Number */ y: { value: 0 }, /** * Indicates whether the shape is visible. * * @config visible * @type Boolean */ visible: { value: true, setter: function(val){ var node = this.get("node"), visibility = val ? "visible" : "hidden"; if(node) { node.style.visibility = visibility; } return val; } }, /** * Contains information about the fill of the shape. *

color

The color of the fill.

opacity

Number between 0 and 1 that indicates the opacity of the fill. The default value is 1.

type

Type of fill. *

solid: Solid single color fill. (default)
linear: Linear gradient fill.
radial: Radial gradient fill.

*

*

If a `linear` or `radial` is specified as the fill type. The following additional property is used: *

stops

An array of objects containing the following properties: *

color: The color of the stop.
opacity: Number between 0 and 1 that indicates the opacity of the stop. The default value is 1. * Note: No effect for IE 6 - 8
offset: Number between 0 and 1 indicating where the color stop is positioned.

*

Linear gradients also have the following property:

rotation

Linear gradients flow left to right by default. The rotation property allows you to change the * flow by rotation. (e.g. A rotation of 180 would make the gradient pain from right to left.)

Radial gradients have the following additional properties:

r

Radius of the gradient circle.

fx

Focal point x-coordinate of the gradient.

fy

Focal point y-coordinate of the gradient.

*

The corresponding `SVGShape` class implements the following additional properties.

*

cx

*

The x-coordinate of the center of the gradient circle. Determines where the color stop begins. The default value 0.5.

*

Note: Currently, this property is not implemented for corresponding `CanvasShape` and * `VMLShape` classes which are used on Android or IE 6 - 8.

*

cy

*

The y-coordinate of the center of the gradient circle. Determines where the color stop begins. The default value 0.5.

*

Note: Currently, this property is not implemented for corresponding `CanvasShape` and `VMLShape` * classes which are used on Android or IE 6 - 8.

*

*

These properties are not currently implemented in `CanvasShape` or `VMLShape`.

* * @config fill * @type Object */ fill: { valueFn: "_getDefaultFill", setter: function(val) { var fill, tmpl = this.get("fill") || this._getDefaultFill(); fill = (val) ? Y.merge(tmpl, val) : null; if(fill && fill.color) { if(fill.color === undefined || fill.color === "none") { fill.color = null; } } this._setFillProps(fill); return fill; } }, /** * Contains information about the stroke of the shape. *

color

The color of the stroke.

weight

Number that indicates the width of the stroke.

opacity

Number between 0 and 1 that indicates the opacity of the stroke. The default value is 1.

dashstyle

linecap

Specifies the linecap for the stroke. The following values can be specified: *

butt (default): Specifies a butt linecap.
square: Specifies a sqare linecap.
round: Specifies a round linecap.

*

linejoin

Specifies a linejoin for the stroke. The following values can be specified: *

round (default): Specifies that the linejoin will be round.
bevel: Specifies a bevel for the linejoin.
miter limit: An integer specifying the miter limit of a miter linejoin. If you want to specify a linejoin * of miter, you simply specify the limit as opposed to having separate miter and miter limit values.

*

* * @config stroke * @type Object */ stroke: { valueFn: "_getDefaultStroke", setter: function(val) { var tmpl = this.get("stroke") || this._getDefaultStroke(), wt; if(val && val.hasOwnProperty("weight")) { wt = parseInt(val.weight, 10); if(!isNaN(wt)) { val.weight = wt; } } val = (val) ? Y.merge(tmpl, val) : null; this._setStrokeProps(val); return val; } }, //Not used. Remove in future. autoSize: { value: false }, // Only implemented in SVG // Determines whether the instance will receive mouse events. // // @config pointerEvents // @type string // pointerEvents: { value: "visiblePainted" }, /** * Represents an SVG Path string. This will be parsed and added to shape's API to represent the SVG data across all * implementations. Note that when using VML or SVG implementations, part of this content will be added to the DOM using * respective VML/SVG attributes. If your content comes from an untrusted source, you will need to ensure that no * malicious code is included in that content. * * @config data * @type String */ data: { setter: function(val) { if(this.get("node")) { this._parsePathData(val); } return val; } }, /** * Reference to the container Graphic. * * @config graphic * @type Graphic */ graphic: { readOnly: true, getter: function() { return this._graphic; } } }; Y.CanvasShape = CanvasShape; /** * Canvas implementation of the `Path` class. * `CanvasPath` is not intended to be used directly. Instead, use the `Path` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Path` * class will point to the `CanvasPath` class. * * @module graphics * @class CanvasPath * @extends CanvasShape */ CanvasPath = function() { CanvasPath.superclass.constructor.apply(this, arguments); }; CanvasPath.NAME = "path"; Y.extend(CanvasPath, Y.CanvasShape, { /** * Indicates the type of shape * * @property _type * @type String * @private */ _type: "path", /** * Draws the shape. * * @method _draw * @private */ _draw: function() { this._closePath(); this._updateTransform(); }, /** * Creates the dom node for the shape. * * @method createNode * @return HTMLElement * @private */ createNode: function() { var host = this, node = Y.config.doc.createElement('canvas'), name = host.name, concat = host._camelCaseConcat, id = host.get("id"); host._context = node.getContext('2d'); node.setAttribute("overflow", "visible"); node.setAttribute("pointer-events", "none"); node.style.pointerEvents = "none"; node.style.overflow = "visible"; node.setAttribute("id", id); id = "#" + id; host.node = node; host.addClass( _getClassName(SHAPE) + " " + _getClassName(concat(IMPLEMENTATION, SHAPE)) + " " + _getClassName(name) + " " + _getClassName(concat(IMPLEMENTATION, name)) ); }, /** * Completes a drawing operation. * * @method end */ end: function() { this._draw(); return this; } }); CanvasPath.ATTRS = Y.merge(Y.CanvasShape.ATTRS, { /** * Indicates the width of the shape * * @config width * @type Number */ width: { getter: function() { var offset = this._stroke && this._strokeWeight ? (this._strokeWeight * 2) : 0; return this._width - offset; }, setter: function(val) { this._width = val; return val; } }, /** * Indicates the height of the shape * * @config height * @type Number */ height: { getter: function() { var offset = this._stroke && this._strokeWeight ? (this._strokeWeight * 2) : 0; return this._height - offset; }, setter: function(val) { this._height = val; return val; } }, /** * Indicates the path used for the node. * * @config path * @type String * @readOnly */ path: { readOnly: true, getter: function() { return this._path; } } }); Y.CanvasPath = CanvasPath; /** * Canvas implementation of the `Rect` class. * `CanvasRect` is not intended to be used directly. Instead, use the `Rect` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Rect` * class will point to the `CanvasRect` class. * * @module graphics * @class CanvasRect * @constructor */ CanvasRect = function() { CanvasRect.superclass.constructor.apply(this, arguments); }; CanvasRect.NAME = "rect"; Y.extend(CanvasRect, Y.CanvasShape, { /** * Indicates the type of shape * * @property _type * @type String * @private */ _type: "rect", /** * Draws the shape. * * @method _draw * @private */ _draw: function() { var w = this.get("width"), h = this.get("height"); this.clear(); this.drawRect(0, 0, w, h); this._closePath(); } }); CanvasRect.ATTRS = Y.CanvasShape.ATTRS; Y.CanvasRect = CanvasRect; /** * Canvas implementation of the `Ellipse` class. * `CanvasEllipse` is not intended to be used directly. Instead, use the `Ellipse` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Ellipse` * class will point to the `CanvasEllipse` class. * * @module graphics * @class CanvasEllipse * @constructor */ CanvasEllipse = function() { CanvasEllipse.superclass.constructor.apply(this, arguments); }; CanvasEllipse.NAME = "ellipse"; Y.extend(CanvasEllipse, CanvasShape, { /** * Indicates the type of shape * * @property _type * @type String * @private */ _type: "ellipse", /** * Draws the shape. * * @method _draw * @private */ _draw: function() { var w = this.get("width"), h = this.get("height"); this.clear(); this.drawEllipse(0, 0, w, h); this._closePath(); } }); CanvasEllipse.ATTRS = Y.merge(CanvasShape.ATTRS, { /** * Horizontal radius for the ellipse. * * @config xRadius * @type Number */ xRadius: { setter: function(val) { this.set("width", val * 2); }, getter: function() { var val = this.get("width"); if(val) { val *= 0.5; } return val; } }, /** * Vertical radius for the ellipse. * * @config yRadius * @type Number * @readOnly */ yRadius: { setter: function(val) { this.set("height", val * 2); }, getter: function() { var val = this.get("height"); if(val) { val *= 0.5; } return val; } } }); Y.CanvasEllipse = CanvasEllipse; /** * Canvas implementation of the `Circle` class. * `CanvasCircle` is not intended to be used directly. Instead, use the `Circle` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Circle` * class will point to the `CanvasCircle` class. * * @module graphics * @class CanvasCircle * @constructor */ CanvasCircle = function() { CanvasCircle.superclass.constructor.apply(this, arguments); }; CanvasCircle.NAME = "circle"; Y.extend(CanvasCircle, Y.CanvasShape, { /** * Indicates the type of shape * * @property _type * @type String * @private */ _type: "circle", /** * Draws the shape. * * @method _draw * @private */ _draw: function() { var radius = this.get("radius"); if(radius) { this.clear(); this.drawCircle(0, 0, radius); this._closePath(); } } }); CanvasCircle.ATTRS = Y.merge(Y.CanvasShape.ATTRS, { /** * Indicates the width of the shape * * @config width * @type Number */ width: { setter: function(val) { this.set("radius", val/2); return val; }, getter: function() { return this.get("radius") * 2; } }, /** * Indicates the height of the shape * * @config height * @type Number */ height: { setter: function(val) { this.set("radius", val/2); return val; }, getter: function() { return this.get("radius") * 2; } }, /** * Radius of the circle * * @config radius * @type Number */ radius: { lazyAdd: false } }); Y.CanvasCircle = CanvasCircle; /** * Draws pie slices * * @module graphics * @class CanvasPieSlice * @constructor */ CanvasPieSlice = function() { CanvasPieSlice.superclass.constructor.apply(this, arguments); }; CanvasPieSlice.NAME = "canvasPieSlice"; Y.extend(CanvasPieSlice, Y.CanvasShape, { /** * Indicates the type of shape * * @property _type * @type String * @private */ _type: "path", /** * Change event listener * * @private * @method _updateHandler */ _draw: function() { var x = this.get("cx"), y = this.get("cy"), startAngle = this.get("startAngle"), arc = this.get("arc"), radius = this.get("radius"); this.clear(); this._left = x; this._right = radius; this._top = y; this._bottom = radius; this.drawWedge(x, y, startAngle, arc, radius); this.end(); } }); CanvasPieSlice.ATTRS = Y.mix({ cx: { value: 0 }, cy: { value: 0 }, /** * Starting angle in relation to a circle in which to begin the pie slice drawing. * * @config startAngle * @type Number */ startAngle: { value: 0 }, /** * Arc of the slice. * * @config arc * @type Number */ arc: { value: 0 }, /** * Radius of the circle in which the pie slice is drawn * * @config radius * @type Number */ radius: { value: 0 } }, Y.CanvasShape.ATTRS); Y.CanvasPieSlice = CanvasPieSlice; /** * Canvas implementation of the `Graphic` class. * `CanvasGraphic` is not intended to be used directly. Instead, use the `Graphic` class. * If the browser lacks SVG capabilities but has * Canvas capabilities, the `Graphic` * class will point to the `CanvasGraphic` class. * * @module graphics * @class CanvasGraphic * @constructor */ function CanvasGraphic() { CanvasGraphic.superclass.constructor.apply(this, arguments); } CanvasGraphic.NAME = "canvasGraphic"; CanvasGraphic.ATTRS = { /** * Whether or not to render the `Graphic` automatically after to a specified parent node after init. This can be a Node * instance or a CSS selector string. * * @config render * @type Node | String */ render: {}, /** * Unique id for class instance. * * @config id * @type String */ id: { valueFn: function() { return Y.guid(); }, setter: function(val) { var node = this._node; if(node) { node.setAttribute("id", val); } return val; } }, /** * Key value pairs in which a shape instance is associated with its id. * * @config shapes * @type Object * @readOnly */ shapes: { readOnly: true, getter: function() { return this._shapes; } }, /** * Object containing size and coordinate data for the content of a Graphic in relation to the graphic instance's position. * * @config contentBounds * @type Object * @readOnly */ contentBounds: { readOnly: true, getter: function() { return this._contentBounds; } }, /** * The outermost html element of the Graphic instance. * * @config node * @type HTMLElement * @readOnly */ node: { readOnly: true, getter: function() { return this._node; } }, /** * Indicates the width of the `Graphic`. * * @config width * @type Number */ width: { setter: function(val) { if(this._node) { this._node.style.width = val + "px"; } return val; } }, /** * Indicates the height of the `Graphic`. * * @config height * @type Number */ height: { setter: function(val) { if(this._node) { this._node.style.height = val + "px"; } return val; } }, /** * Determines the sizing of the Graphic. * *

sizeContentToGraphic: The Graphic's width and height attributes are, either explicitly set through the * width and height attributes or are determined by the dimensions of the parent element. The * content contained in the Graphic will be sized to fit with in the Graphic instance's dimensions. When using this * setting, the preserveAspectRatio attribute will determine how the contents are sized.
sizeGraphicToContent: (Also accepts a value of true) The Graphic's width and height are determined by the * size and positioning of the content.
false: The Graphic's width and height attributes are, either explicitly set through the width * and height attributes or are determined by the dimensions of the parent element. The contents of the * Graphic instance are not affected by this setting.

* * * @config autoSize * @type Boolean | String * @default false */ autoSize: { value: false }, /** * Determines how content is sized when autoSize is set to sizeContentToGraphic. * *

none
: Do not force uniform scaling. Scale the graphic content of the given element non-uniformly if necessary * such that the element's bounding box exactly matches the viewport rectangle.
xMinYMin: Force uniform scaling position along the top left of the Graphic's node.
xMidYMin: Force uniform scaling horizontally centered and positioned at the top of the Graphic's node.; *
xMaxYMin: Force uniform scaling positioned horizontally from the right and vertically from the top.
xMinYMid
xMidYMid (the default): Force uniform scaling with the content centered.
xMaxYMid: Force uniform scaling positioned horizontally from the right and vertically centered.
xMinYMax: Force uniform scaling positioned horizontally from the left and vertically from the bottom.
xMidYMax: Force uniform scaling horizontally centered and position vertically from the bottom.
xMaxYMax: Force uniform scaling positioned horizontally from the right and vertically from the bottom.

* * @config preserveAspectRatio * @type String * @default xMidYMid */ preserveAspectRatio: { value: "xMidYMid" }, /** * The contentBounds will resize to greater values but not smaller values. (for performance) * When resizing the contentBounds down is desirable, set the resizeDown value to true. * * @config resizeDown * @type Boolean */ resizeDown: { value: false }, /** * Indicates the x-coordinate for the instance. * * @config x * @type Number */ x: { getter: function() { return this._x; }, setter: function(val) { this._x = val; if(this._node) { this._node.style.left = val + "px"; } return val; } }, /** * Indicates the y-coordinate for the instance. * * @config y * @type Number */ y: { getter: function() { return this._y; }, setter: function(val) { this._y = val; if(this._node) { this._node.style.top = val + "px"; } return val; } }, /** * Indicates whether or not the instance will automatically redraw after a change is made to a shape. * This property will get set to false when batching operations. * * @config autoDraw * @type Boolean * @default true * @private */ autoDraw: { value: true }, /** * Indicates whether the `Graphic` and its children are visible. * * @config visible * @type Boolean */ visible: { value: true, setter: function(val) { this._toggleVisible(val); return val; } } }; Y.extend(CanvasGraphic, Y.GraphicBase, { /** * Sets the value of an attribute. * * @method set * @param {String|Object} name The name of the attribute. Alternatively, an object of key value pairs can * be passed in to set multiple attributes at once. * @param {Any} value The value to set the attribute to. This value is ignored if an object is received as * the name param. */ set: function() { var host = this, attr = arguments[0], redrawAttrs = { autoDraw: true, autoSize: true, preserveAspectRatio: true, resizeDown: true }, key, forceRedraw = false; AttributeLite.prototype.set.apply(host, arguments); if(host._state.autoDraw === true && Y.Object.size(this._shapes) > 0) { if(Y_LANG.isString && redrawAttrs[attr]) { forceRedraw = true; } else if(Y_LANG.isObject(attr)) { for(key in redrawAttrs) { if(redrawAttrs.hasOwnProperty(key) && attr[key]) { forceRedraw = true; break; } } } } if(forceRedraw) { host._redraw(); } }, /** * Storage for `x` attribute. * * @property _x * @type Number * @private */ _x: 0, /** * Storage for `y` attribute. * * @property _y * @type Number * @private */ _y: 0, /** * Gets the current position of the graphic instance in page coordinates. * * @method getXY * @return Array The XY position of the shape. */ getXY: function() { var node = this._node, xy; if(node) { xy = Y.DOM.getXY(node); } return xy; }, /** * Initializes the class. * * @method initializer * @param {Object} config Optional attributes * @private */ initializer: function() { var render = this.get("render"), visibility = this.get("visible") ? "visible" : "hidden", w = this.get("width") || 0, h = this.get("height") || 0; this._shapes = {}; this._redrawQueue = {}; this._contentBounds = { left: 0, top: 0, right: 0, bottom: 0 }; this._node = DOCUMENT.createElement('div'); this._node.style.position = "absolute"; this._node.style.visibility = visibility; this.set("width", w); this.set("height", h); if(render) { this.render(render); } }, /** * Adds the graphics node to the dom. * * @method render * @param {HTMLElement} parentNode node in which to render the graphics node into. */ render: function(render) { var parentNode = render || DOCUMENT.body, node = this._node, w, h; if(render instanceof Y.Node) { parentNode = render._node; } else if(Y.Lang.isString(render)) { parentNode = Y.Selector.query(render, DOCUMENT.body, true); } w = this.get("width") || parseInt(Y.DOM.getComputedStyle(parentNode, "width"), 10); h = this.get("height") || parseInt(Y.DOM.getComputedStyle(parentNode, "height"), 10); parentNode.appendChild(node); node.style.display = "block"; node.style.position = "absolute"; node.style.left = this.get("x") + "px"; node.style.top = this.get("y") + "px"; this.set("width", w); this.set("height", h); this.parentNode = parentNode; return this; }, /** * Removes all nodes. * * @method destroy */ destroy: function() { this.removeAllShapes(); if(this._node) { this._removeChildren(this._node); if(this._node.parentNode) { this._node.parentNode.removeChild(this._node); } this._node = null; } }, /** * Generates a shape instance by type. * * @method addShape * @param {Object} cfg attributes for the shape * @return Shape */ addShape: function(cfg) { cfg.graphic = this; if(!this.get("visible")) { cfg.visible = false; } var ShapeClass = this._getShapeClass(cfg.type), shape = new ShapeClass(cfg); this._appendShape(shape); return shape; }, /** * Adds a shape instance to the graphic instance. * * @method _appendShape * @param {Shape} shape The shape instance to be added to the graphic. * @private */ _appendShape: function(shape) { var node = shape.node, parentNode = this._frag || this._node; if(this.get("autoDraw")) { parentNode.appendChild(node); } else { this._getDocFrag().appendChild(node); } }, /** * Removes a shape instance from from the graphic instance. * * @method removeShape * @param {Shape|String} shape The instance or id of the shape to be removed. */ removeShape: function(shape) { if(!(shape instanceof CanvasShape)) { if(Y_LANG.isString(shape)) { shape = this._shapes[shape]; } } if(shape && shape instanceof CanvasShape) { shape._destroy(); delete this._shapes[shape.get("id")]; } if(this.get("autoDraw")) { this._redraw(); } return shape; }, /** * Removes all shape instances from the dom. * * @method removeAllShapes */ removeAllShapes: function() { var shapes = this._shapes, i; for(i in shapes) { if(shapes.hasOwnProperty(i)) { shapes[i].destroy(); } } this._shapes = {}; }, /** * Clears the graphics object. * * @method clear */ clear: function() { this.removeAllShapes(); }, /** * Removes all child nodes. * * @method _removeChildren * @param {HTMLElement} node * @private */ _removeChildren: function(node) { if(node && node.hasChildNodes()) { var child; while(node.firstChild) { child = node.firstChild; this._removeChildren(child); node.removeChild(child); } } }, /** * Toggles visibility * * @method _toggleVisible * @param {Boolean} val indicates visibilitye * @private */ _toggleVisible: function(val) { var i, shapes = this._shapes, visibility = val ? "visible" : "hidden"; if(shapes) { for(i in shapes) { if(shapes.hasOwnProperty(i)) { shapes[i].set("visible", val); } } } if(this._node) { this._node.style.visibility = visibility; } }, /** * Returns a shape class. Used by `addShape`. * * @method _getShapeClass * @param {Shape | String} val Indicates which shape class. * @return Function * @private */ _getShapeClass: function(val) { var shape = this._shapeClass[val]; if(shape) { return shape; } return val; }, /** * Look up for shape classes. Used by `addShape` to retrieve a class for instantiation. * * @property _shapeClass * @type Object * @private */ _shapeClass: { circle: Y.CanvasCircle, rect: Y.CanvasRect, path: Y.CanvasPath, ellipse: Y.CanvasEllipse, pieslice: Y.CanvasPieSlice }, /** * Returns a shape based on the id of its dom node. * * @method getShapeById * @param {String} id Dom id of the shape's node attribute. * @return Shape */ getShapeById: function(id) { var shape = this._shapes[id]; return shape; }, /** * Allows for creating multiple shapes in order to batch appending and redraw operations. * * @method batch * @param {Function} method Method to execute. */ batch: function(method) { var autoDraw = this.get("autoDraw"); this.set("autoDraw", false); method(); this.set("autoDraw", autoDraw); }, /** * Returns a document fragment to for attaching shapes. * * @method _getDocFrag * @return DocumentFragment * @private */ _getDocFrag: function() { if(!this._frag) { this._frag = DOCUMENT.createDocumentFragment(); } return this._frag; }, /** * Redraws all shapes. * * @method _redraw * @private */ _redraw: function() { var autoSize = this.get("autoSize"), preserveAspectRatio = this.get("preserveAspectRatio"), box = this.get("resizeDown") ? this._getUpdatedContentBounds() : this._contentBounds, contentWidth, contentHeight, w, h, xScale, yScale, translateX = 0, translateY = 0, matrix, node = this.get("node"); if(autoSize) { if(autoSize === "sizeContentToGraphic") { contentWidth = box.right - box.left; contentHeight = box.bottom - box.top; w = parseFloat(Y_DOM.getComputedStyle(node, "width")); h = parseFloat(Y_DOM.getComputedStyle(node, "height")); matrix = new Y.Matrix(); if(preserveAspectRatio === "none") { xScale = w/contentWidth; yScale = h/contentHeight; } else { if(contentWidth/contentHeight !== w/h) { if(contentWidth * h/contentHeight > w) { xScale = yScale = w/contentWidth; translateY = this._calculateTranslate(preserveAspectRatio.slice(5).toLowerCase(), contentHeight * w/contentWidth, h); } else { xScale = yScale = h/contentHeight; translateX = this._calculateTranslate(preserveAspectRatio.slice(1, 4).toLowerCase(), contentWidth * h/contentHeight, w); } } } Y_DOM.setStyle(node, "transformOrigin", "0% 0%"); translateX = translateX - (box.left * xScale); translateY = translateY - (box.top * yScale); matrix.translate(translateX, translateY); matrix.scale(xScale, yScale); Y_DOM.setStyle(node, "transform", matrix.toCSSText()); } else { this.set("width", box.right); this.set("height", box.bottom); } } if(this._frag) { this._node.appendChild(this._frag); this._frag = null; } }, /** * Determines the value for either an x or y value to be used for the translate of the Graphic. * * @method _calculateTranslate * @param {String} position The position for placement. Possible values are min, mid and max. * @param {Number} contentSize The total size of the content. * @param {Number} boundsSize The total size of the Graphic. * @return Number * @private */ _calculateTranslate: function(position, contentSize, boundsSize) { var ratio = boundsSize - contentSize, coord; switch(position) { case "mid" : coord = ratio * 0.5; break; case "max" : coord = ratio; break; default : coord = 0; break; } return coord; }, /** * Adds a shape to the redraw queue and calculates the contentBounds. Used internally * by `Shape` instances. * * @method addToRedrawQueue * @param Shape shape The shape instance to add to the queue * @protected */ addToRedrawQueue: function(shape) { var shapeBox, box; this._shapes[shape.get("id")] = shape; if(!this.get("resizeDown")) { shapeBox = shape.getBounds(); box = this._contentBounds; box.left = box.left < shapeBox.left ? box.left : shapeBox.left; box.top = box.top < shapeBox.top ? box.top : shapeBox.top; box.right = box.right > shapeBox.right ? box.right : shapeBox.right; box.bottom = box.bottom > shapeBox.bottom ? box.bottom : shapeBox.bottom; this._contentBounds = box; } if(this.get("autoDraw")) { this._redraw(); } }, /** * Recalculates and returns the `contentBounds` for the `Graphic` instance. * * @method _getUpdatedContentBounds * @return {Object} * @private */ _getUpdatedContentBounds: function() { var bounds, i, shape, queue = this._shapes, box = {}; for(i in queue) { if(queue.hasOwnProperty(i)) { shape = queue[i]; bounds = shape.getBounds(); box.left = Y_LANG.isNumber(box.left) ? Math.min(box.left, bounds.left) : bounds.left; box.top = Y_LANG.isNumber(box.top) ? Math.min(box.top, bounds.top) : bounds.top; box.right = Y_LANG.isNumber(box.right) ? Math.max(box.right, bounds.right) : bounds.right; box.bottom = Y_LANG.isNumber(box.bottom) ? Math.max(box.bottom, bounds.bottom) : bounds.bottom; } } box.left = Y_LANG.isNumber(box.left) ? box.left : 0; box.top = Y_LANG.isNumber(box.top) ? box.top : 0; box.right = Y_LANG.isNumber(box.right) ? box.right : 0; box.bottom = Y_LANG.isNumber(box.bottom) ? box.bottom : 0; this._contentBounds = box; return box; }, /** * Inserts shape on the top of the tree. * * @method _toFront * @param {CanvasShape} Shape to add. * @private */ _toFront: function(shape) { var contentNode = this.get("node"); if(shape instanceof Y.CanvasShape) { shape = shape.get("node"); } if(contentNode && shape) { contentNode.appendChild(shape); } }, /** * Inserts shape as the first child of the content node. * * @method _toBack * @param {CanvasShape} Shape to add. * @private */ _toBack: function(shape) { var contentNode = this.get("node"), targetNode; if(shape instanceof Y.CanvasShape) { shape = shape.get("node"); } if(contentNode && shape) { targetNode = contentNode.firstChild; if(targetNode) { contentNode.insertBefore(shape, targetNode); } else { contentNode.appendChild(shape); } } } }); Y.CanvasGraphic = CanvasGraphic; }, '3.17.2', {"requires": ["graphics", "color-base"]});