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Viewing file: Elements.js (31.79 KB) -rw-rw-rw- Select action/file-type: (+) | (+) | (+) | Code (+) | Session (+) | (+) | SDB (+) | (+) | (+) | (+) | (+) | (+) | /* Copyright (c) 2006-2010 by OpenLayers Contributors (see authors.txt for * full list of contributors). Published under the Clear BSD license. * See http://svn.openlayers.org/trunk/openlayers/license.txt for the * full text of the license. */ /** * @requires OpenLayers/Renderer.js */ /** * Class: OpenLayers.ElementsIndexer * This class takes care of figuring out which order elements should be * placed in the DOM based on given indexing methods. */ OpenLayers.ElementsIndexer = OpenLayers.Class({ /** * Property: maxZIndex * {Integer} This is the largest-most z-index value for a node * contained within the indexer. */ maxZIndex: null, /** * Property: order * {Array<String>} This is an array of node id's stored in the * order that they should show up on screen. Id's higher up in the * array (higher array index) represent nodes with higher z-indeces. */ order: null, /** * Property: indices * {Object} This is a hash that maps node ids to their z-index value * stored in the indexer. This is done to make finding a nodes z-index * value O(1). */ indices: null, /** * Property: compare * {Function} This is the function used to determine placement of * of a new node within the indexer. If null, this defaults to to * the Z_ORDER_DRAWING_ORDER comparison method. */ compare: null, /** * APIMethod: initialize * Create a new indexer with * * Parameters: * yOrdering - {Boolean} Whether to use y-ordering. */ initialize: function(yOrdering) { this.compare = yOrdering ? OpenLayers.ElementsIndexer.IndexingMethods.Z_ORDER_Y_ORDER : OpenLayers.ElementsIndexer.IndexingMethods.Z_ORDER_DRAWING_ORDER; this.order = []; this.indices = {}; this.maxZIndex = 0; }, /** * APIMethod: insert * Insert a new node into the indexer. In order to find the correct * positioning for the node to be inserted, this method uses a binary * search. This makes inserting O(log(n)). * * Parameters: * newNode - {DOMElement} The new node to be inserted. * * Returns * {DOMElement} the node before which we should insert our newNode, or * null if newNode can just be appended. */ insert: function(newNode) { // If the node is known to the indexer, remove it so we can // recalculate where it should go. if (this.exists(newNode)) { this.remove(newNode); } var nodeId = newNode.id; this.determineZIndex(newNode); var leftIndex = -1; var rightIndex = this.order.length; var middle; while (rightIndex - leftIndex > 1) { middle = parseInt((leftIndex + rightIndex) / 2); var placement = this.compare(this, newNode, OpenLayers.Util.getElement(this.order[middle])); if (placement > 0) { leftIndex = middle; } else { rightIndex = middle; } } this.order.splice(rightIndex, 0, nodeId); this.indices[nodeId] = this.getZIndex(newNode); // If the new node should be before another in the index // order, return the node before which we have to insert the new one; // else, return null to indicate that the new node can be appended. return this.getNextElement(rightIndex); }, /** * APIMethod: remove * * Parameters: * node - {DOMElement} The node to be removed. */ remove: function(node) { var nodeId = node.id; var arrayIndex = OpenLayers.Util.indexOf(this.order, nodeId); if (arrayIndex >= 0) { // Remove it from the order array, as well as deleting the node // from the indeces hash. this.order.splice(arrayIndex, 1); delete this.indices[nodeId]; // Reset the maxium z-index based on the last item in the // order array. if (this.order.length > 0) { var lastId = this.order[this.order.length - 1]; this.maxZIndex = this.indices[lastId]; } else { this.maxZIndex = 0; } } }, /** * APIMethod: clear */ clear: function() { this.order = []; this.indices = {}; this.maxZIndex = 0; }, /** * APIMethod: exists * * Parameters: * node- {DOMElement} The node to test for existence. * * Returns: * {Boolean} Whether or not the node exists in the indexer? */ exists: function(node) { return (this.indices[node.id] != null); }, /** * APIMethod: getZIndex * Get the z-index value for the current node from the node data itself. * * Parameters: * node - {DOMElement} The node whose z-index to get. * * Returns: * {Integer} The z-index value for the specified node (from the node * data itself). */ getZIndex: function(node) { return node._style.graphicZIndex; }, /** * Method: determineZIndex * Determine the z-index for the current node if there isn't one, * and set the maximum value if we've found a new maximum. * * Parameters: * node - {DOMElement} */ determineZIndex: function(node) { var zIndex = node._style.graphicZIndex; // Everything must have a zIndex. If none is specified, // this means the user *must* (hint: assumption) want this // node to succomb to drawing order. To enforce drawing order // over all indexing methods, we'll create a new z-index that's // greater than any currently in the indexer. if (zIndex == null) { zIndex = this.maxZIndex; node._style.graphicZIndex = zIndex; } else if (zIndex > this.maxZIndex) { this.maxZIndex = zIndex; } }, /** * APIMethod: getNextElement * Get the next element in the order stack. * * Parameters: * index - {Integer} The index of the current node in this.order. * * Returns: * {DOMElement} the node following the index passed in, or * null. */ getNextElement: function(index) { var nextIndex = index + 1; if (nextIndex < this.order.length) { var nextElement = OpenLayers.Util.getElement(this.order[nextIndex]); if (nextElement == undefined) { nextElement = this.getNextElement(nextIndex); } return nextElement; } else { return null; } }, CLASS_NAME: "OpenLayers.ElementsIndexer" }); /** * Namespace: OpenLayers.ElementsIndexer.IndexingMethods * These are the compare methods for figuring out where a new node should be * placed within the indexer. These methods are very similar to general * sorting methods in that they return -1, 0, and 1 to specify the * direction in which new nodes fall in the ordering. */ OpenLayers.ElementsIndexer.IndexingMethods = { /** * Method: Z_ORDER * This compare method is used by other comparison methods. * It can be used individually for ordering, but is not recommended, * because it doesn't subscribe to drawing order. * * Parameters: * indexer - {<OpenLayers.ElementsIndexer>} * newNode - {DOMElement} * nextNode - {DOMElement} * * Returns: * {Integer} */ Z_ORDER: function(indexer, newNode, nextNode) { var newZIndex = indexer.getZIndex(newNode); var returnVal = 0; if (nextNode) { var nextZIndex = indexer.getZIndex(nextNode); returnVal = newZIndex - nextZIndex; } return returnVal; }, /** * APIMethod: Z_ORDER_DRAWING_ORDER * This method orders nodes by their z-index, but does so in a way * that, if there are other nodes with the same z-index, the newest * drawn will be the front most within that z-index. This is the * default indexing method. * * Parameters: * indexer - {<OpenLayers.ElementsIndexer>} * newNode - {DOMElement} * nextNode - {DOMElement} * * Returns: * {Integer} */ Z_ORDER_DRAWING_ORDER: function(indexer, newNode, nextNode) { var returnVal = OpenLayers.ElementsIndexer.IndexingMethods.Z_ORDER( indexer, newNode, nextNode ); // Make Z_ORDER subscribe to drawing order by pushing it above // all of the other nodes with the same z-index. if (nextNode && returnVal == 0) { returnVal = 1; } return returnVal; }, /** * APIMethod: Z_ORDER_Y_ORDER * This one should really be called Z_ORDER_Y_ORDER_DRAWING_ORDER, as it * best describes which ordering methods have precedence (though, the * name would be too long). This method orders nodes by their z-index, * but does so in a way that, if there are other nodes with the same * z-index, the nodes with the lower y position will be "closer" than * those with a higher y position. If two nodes have the exact same y * position, however, then this method will revert to using drawing * order to decide placement. * * Parameters: * indexer - {<OpenLayers.ElementsIndexer>} * newNode - {DOMElement} * nextNode - {DOMElement} * * Returns: * {Integer} */ Z_ORDER_Y_ORDER: function(indexer, newNode, nextNode) { var returnVal = OpenLayers.ElementsIndexer.IndexingMethods.Z_ORDER( indexer, newNode, nextNode ); if (nextNode && returnVal === 0) { var result = nextNode._boundsBottom - newNode._boundsBottom; returnVal = (result === 0) ? 1 : result; } return returnVal; } }; /** * Class: OpenLayers.Renderer.Elements * This is another virtual class in that it should never be instantiated by * itself as a Renderer. It exists because there is *tons* of shared * functionality between different vector libraries which use nodes/elements * as a base for rendering vectors. * * The highlevel bits of code that are implemented here are the adding and * removing of geometries, which is essentially the same for any * element-based renderer. The details of creating each node and drawing the * paths are of course different, but the machinery is the same. * * Inherits: * - <OpenLayers.Renderer> */ OpenLayers.Renderer.Elements = OpenLayers.Class(OpenLayers.Renderer, { /** * Property: rendererRoot * {DOMElement} */ rendererRoot: null, /** * Property: root * {DOMElement} */ root: null, /** * Property: vectorRoot * {DOMElement} */ vectorRoot: null, /** * Property: textRoot * {DOMElement} */ textRoot: null, /** * Property: xmlns * {String} */ xmlns: null, /** * Property: Indexer * {<OpenLayers.ElementIndexer>} An instance of OpenLayers.ElementsIndexer * created upon initialization if the zIndexing or yOrdering options * passed to this renderer's constructor are set to true. */ indexer: null, /** * Constant: BACKGROUND_ID_SUFFIX * {String} */ BACKGROUND_ID_SUFFIX: "_background", /** * Constant: BACKGROUND_ID_SUFFIX * {String} */ LABEL_ID_SUFFIX: "_label", /** * Constructor: OpenLayers.Renderer.Elements * * Parameters: * containerID - {String} * options - {Object} options for this renderer. Supported options are: * * yOrdering - {Boolean} Whether to use y-ordering * * zIndexing - {Boolean} Whether to use z-indexing. Will be ignored * if yOrdering is set to true. */ initialize: function(containerID, options) { OpenLayers.Renderer.prototype.initialize.apply(this, arguments); this.rendererRoot = this.createRenderRoot(); this.root = this.createRoot("_root"); this.vectorRoot = this.createRoot("_vroot"); this.textRoot = this.createRoot("_troot"); this.root.appendChild(this.vectorRoot); this.root.appendChild(this.textRoot); this.rendererRoot.appendChild(this.root); this.container.appendChild(this.rendererRoot); if(options && (options.zIndexing || options.yOrdering)) { this.indexer = new OpenLayers.ElementsIndexer(options.yOrdering); } }, /** * Method: destroy */ destroy: function() { this.clear(); this.rendererRoot = null; this.root = null; this.xmlns = null; OpenLayers.Renderer.prototype.destroy.apply(this, arguments); }, /** * Method: clear * Remove all the elements from the root */ clear: function() { var child; var root = this.vectorRoot; if (root) { while (child = root.firstChild) { root.removeChild(child); } } root = this.textRoot; if (root) { while (child = root.firstChild) { root.removeChild(child); } } if (this.indexer) { this.indexer.clear(); } }, /** * Method: getNodeType * This function is in charge of asking the specific renderer which type * of node to create for the given geometry and style. All geometries * in an Elements-based renderer consist of one node and some * attributes. We have the nodeFactory() function which creates a node * for us, but it takes a 'type' as input, and that is precisely what * this function tells us. * * Parameters: * geometry - {<OpenLayers.Geometry>} * style - {Object} * * Returns: * {String} The corresponding node type for the specified geometry */ getNodeType: function(geometry, style) { }, /** * Method: drawGeometry * Draw the geometry, creating new nodes, setting paths, setting style, * setting featureId on the node. This method should only be called * by the renderer itself. * * Parameters: * geometry - {<OpenLayers.Geometry>} * style - {Object} * featureId - {String} * * Returns: * {Boolean} true if the geometry has been drawn completely; null if * incomplete; false otherwise */ drawGeometry: function(geometry, style, featureId) { var className = geometry.CLASS_NAME; var rendered = true; if ((className == "OpenLayers.Geometry.Collection") || (className == "OpenLayers.Geometry.MultiPoint") || (className == "OpenLayers.Geometry.MultiLineString") || (className == "OpenLayers.Geometry.MultiPolygon")) { for (var i = 0, len=geometry.components.length; i<len; i++) { rendered = this.drawGeometry( geometry.components[i], style, featureId) && rendered; } return rendered; }; rendered = false; if (style.display != "none") { if (style.backgroundGraphic) { this.redrawBackgroundNode(geometry.id, geometry, style, featureId); } rendered = this.redrawNode(geometry.id, geometry, style, featureId); } if (rendered == false) { var node = document.getElementById(geometry.id); if (node) { if (node._style.backgroundGraphic) { node.parentNode.removeChild(document.getElementById( geometry.id + this.BACKGROUND_ID_SUFFIX)); } node.parentNode.removeChild(node); } } return rendered; }, /** * Method: redrawNode * * Parameters: * id - {String} * geometry - {<OpenLayers.Geometry>} * style - {Object} * featureId - {String} * * Returns: * {Boolean} true if the complete geometry could be drawn, null if parts of * the geometry could not be drawn, false otherwise */ redrawNode: function(id, geometry, style, featureId) { style = this.applyDefaultSymbolizer(style); // Get the node if it's already on the map. var node = this.nodeFactory(id, this.getNodeType(geometry, style)); // Set the data for the node, then draw it. node._featureId = featureId; node._boundsBottom = geometry.getBounds().bottom; node._geometryClass = geometry.CLASS_NAME; node._style = style; var drawResult = this.drawGeometryNode(node, geometry, style); if(drawResult === false) { return false; } node = drawResult.node; // Insert the node into the indexer so it can show us where to // place it. Note that this operation is O(log(n)). If there's a // performance problem (when dragging, for instance) this is // likely where it would be. if (this.indexer) { var insert = this.indexer.insert(node); if (insert) { this.vectorRoot.insertBefore(node, insert); } else { this.vectorRoot.appendChild(node); } } else { // if there's no indexer, simply append the node to root, // but only if the node is a new one if (node.parentNode !== this.vectorRoot){ this.vectorRoot.appendChild(node); } } this.postDraw(node); return drawResult.complete; }, /** * Method: redrawBackgroundNode * Redraws the node using special 'background' style properties. Basically * just calls redrawNode(), but instead of directly using the * 'externalGraphic', 'graphicXOffset', 'graphicYOffset', and * 'graphicZIndex' properties directly from the specified 'style' * parameter, we create a new style object and set those properties * from the corresponding 'background'-prefixed properties from * specified 'style' parameter. * * Parameters: * id - {String} * geometry - {<OpenLayers.Geometry>} * style - {Object} * featureId - {String} * * Returns: * {Boolean} true if the complete geometry could be drawn, null if parts of * the geometry could not be drawn, false otherwise */ redrawBackgroundNode: function(id, geometry, style, featureId) { var backgroundStyle = OpenLayers.Util.extend({}, style); // Set regular style attributes to apply to the background styles. backgroundStyle.externalGraphic = backgroundStyle.backgroundGraphic; backgroundStyle.graphicXOffset = backgroundStyle.backgroundXOffset; backgroundStyle.graphicYOffset = backgroundStyle.backgroundYOffset; backgroundStyle.graphicZIndex = backgroundStyle.backgroundGraphicZIndex; backgroundStyle.graphicWidth = backgroundStyle.backgroundWidth || backgroundStyle.graphicWidth; backgroundStyle.graphicHeight = backgroundStyle.backgroundHeight || backgroundStyle.graphicHeight; // Erase background styles. backgroundStyle.backgroundGraphic = null; backgroundStyle.backgroundXOffset = null; backgroundStyle.backgroundYOffset = null; backgroundStyle.backgroundGraphicZIndex = null; return this.redrawNode( id + this.BACKGROUND_ID_SUFFIX, geometry, backgroundStyle, null ); }, /** * Method: drawGeometryNode * Given a node, draw a geometry on the specified layer. * node and geometry are required arguments, style is optional. * This method is only called by the render itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * style - {Object} * * Returns: * {Object} a hash with properties "node" (the drawn node) and "complete" * (null if parts of the geometry could not be drawn, false if nothing * could be drawn) */ drawGeometryNode: function(node, geometry, style) { style = style || node._style; var options = { 'isFilled': style.fill === undefined ? true : style.fill, 'isStroked': style.stroke === undefined ? !!style.strokeWidth : style.stroke }; var drawn; switch (geometry.CLASS_NAME) { case "OpenLayers.Geometry.Point": if(style.graphic === false) { options.isFilled = false; options.isStroked = false; } drawn = this.drawPoint(node, geometry); break; case "OpenLayers.Geometry.LineString": options.isFilled = false; drawn = this.drawLineString(node, geometry); break; case "OpenLayers.Geometry.LinearRing": drawn = this.drawLinearRing(node, geometry); break; case "OpenLayers.Geometry.Polygon": drawn = this.drawPolygon(node, geometry); break; case "OpenLayers.Geometry.Surface": drawn = this.drawSurface(node, geometry); break; case "OpenLayers.Geometry.Rectangle": drawn = this.drawRectangle(node, geometry); break; default: break; } node._options = options; //set style //TBD simplify this if (drawn != false) { return { node: this.setStyle(node, style, options, geometry), complete: drawn }; } else { return false; } }, /** * Method: postDraw * Things that have do be done after the geometry node is appended * to its parent node. To be overridden by subclasses. * * Parameters: * node - {DOMElement} */ postDraw: function(node) {}, /** * Method: drawPoint * Virtual function for drawing Point Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or false if the renderer could not draw the point */ drawPoint: function(node, geometry) {}, /** * Method: drawLineString * Virtual function for drawing LineString Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or null if the renderer could not draw all components of * the linestring, or false if nothing could be drawn */ drawLineString: function(node, geometry) {}, /** * Method: drawLinearRing * Virtual function for drawing LinearRing Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or null if the renderer could not draw all components * of the linear ring, or false if nothing could be drawn */ drawLinearRing: function(node, geometry) {}, /** * Method: drawPolygon * Virtual function for drawing Polygon Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or null if the renderer could not draw all components * of the polygon, or false if nothing could be drawn */ drawPolygon: function(node, geometry) {}, /** * Method: drawRectangle * Virtual function for drawing Rectangle Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or false if the renderer could not draw the rectangle */ drawRectangle: function(node, geometry) {}, /** * Method: drawCircle * Virtual function for drawing Circle Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or false if the renderer could not draw the circle */ drawCircle: function(node, geometry) {}, /** * Method: drawSurface * Virtual function for drawing Surface Geometry. * Should be implemented by subclasses. * This method is only called by the renderer itself. * * Parameters: * node - {DOMElement} * geometry - {<OpenLayers.Geometry>} * * Returns: * {DOMElement} or false if the renderer could not draw the surface */ drawSurface: function(node, geometry) {}, /** * Method: removeText * Removes a label * * Parameters: * featureId - {String} */ removeText: function(featureId) { var label = document.getElementById(featureId + this.LABEL_ID_SUFFIX); if (label) { this.textRoot.removeChild(label); } }, /** * Method: getFeatureIdFromEvent * * Parameters: * evt - {Object} An <OpenLayers.Event> object * * Returns: * {<OpenLayers.Geometry>} A geometry from an event that * happened on a layer. */ getFeatureIdFromEvent: function(evt) { var target = evt.target; var useElement = target && target.correspondingUseElement; var node = useElement ? useElement : (target || evt.srcElement); var featureId = node._featureId; return featureId; }, /** * Method: eraseGeometry * Erase a geometry from the renderer. In the case of a multi-geometry, * we cycle through and recurse on ourselves. Otherwise, we look for a * node with the geometry.id, destroy its geometry, and remove it from * the DOM. * * Parameters: * geometry - {<OpenLayers.Geometry>} * featureId - {String} */ eraseGeometry: function(geometry, featureId) { if ((geometry.CLASS_NAME == "OpenLayers.Geometry.MultiPoint") || (geometry.CLASS_NAME == "OpenLayers.Geometry.MultiLineString") || (geometry.CLASS_NAME == "OpenLayers.Geometry.MultiPolygon") || (geometry.CLASS_NAME == "OpenLayers.Geometry.Collection")) { for (var i=0, len=geometry.components.length; i<len; i++) { this.eraseGeometry(geometry.components[i], featureId); } } else { var element = OpenLayers.Util.getElement(geometry.id); if (element && element.parentNode) { if (element.geometry) { element.geometry.destroy(); element.geometry = null; } element.parentNode.removeChild(element); if (this.indexer) { this.indexer.remove(element); } if (element._style.backgroundGraphic) { var backgroundId = geometry.id + this.BACKGROUND_ID_SUFFIX; var bElem = OpenLayers.Util.getElement(backgroundId); if (bElem && bElem.parentNode) { // No need to destroy the geometry since the element and the background // node share the same geometry. bElem.parentNode.removeChild(bElem); } } } } }, /** * Method: nodeFactory * Create new node of the specified type, with the (optional) specified id. * * If node already exists with same ID and a different type, we remove it * and then call ourselves again to recreate it. * * Parameters: * id - {String} * type - {String} type Kind of node to draw. * * Returns: * {DOMElement} A new node of the given type and id. */ nodeFactory: function(id, type) { var node = OpenLayers.Util.getElement(id); if (node) { if (!this.nodeTypeCompare(node, type)) { node.parentNode.removeChild(node); node = this.nodeFactory(id, type); } } else { node = this.createNode(type, id); } return node; }, /** * Method: nodeTypeCompare * * Parameters: * node - {DOMElement} * type - {String} Kind of node * * Returns: * {Boolean} Whether or not the specified node is of the specified type * This function must be overridden by subclasses. */ nodeTypeCompare: function(node, type) {}, /** * Method: createNode * * Parameters: * type - {String} Kind of node to draw. * id - {String} Id for node. * * Returns: * {DOMElement} A new node of the given type and id. * This function must be overridden by subclasses. */ createNode: function(type, id) {}, /** * Method: moveRoot * moves this renderer's root to a different renderer. * * Parameters: * renderer - {<OpenLayers.Renderer>} target renderer for the moved root */ moveRoot: function(renderer) { var root = this.root; if(renderer.root.parentNode == this.rendererRoot) { root = renderer.root; } root.parentNode.removeChild(root); renderer.rendererRoot.appendChild(root); }, /** * Method: getRenderLayerId * Gets the layer that this renderer's output appears on. If moveRoot was * used, this will be different from the id of the layer containing the * features rendered by this renderer. * * Returns: * {String} the id of the output layer. */ getRenderLayerId: function() { return this.root.parentNode.parentNode.id; }, /** * Method: isComplexSymbol * Determines if a symbol cannot be rendered using drawCircle * * Parameters: * graphicName - {String} * * Returns * {Boolean} true if the symbol is complex, false if not */ isComplexSymbol: function(graphicName) { return (graphicName != "circle") && !!graphicName; }, CLASS_NAME: "OpenLayers.Renderer.Elements" }); /** * Constant: OpenLayers.Renderer.symbol * Coordinate arrays for well known (named) symbols. */ OpenLayers.Renderer.symbol = { "star": [350,75, 379,161, 469,161, 397,215, 423,301, 350,250, 277,301, 303,215, 231,161, 321,161, 350,75], "cross": [4,0, 6,0, 6,4, 10,4, 10,6, 6,6, 6,10, 4,10, 4,6, 0,6, 0,4, 4,4, 4,0], "x": [0,0, 25,0, 50,35, 75,0, 100,0, 65,50, 100,100, 75,100, 50,65, 25,100, 0,100, 35,50, 0,0], "square": [0,0, 0,1, 1,1, 1,0, 0,0], "triangle": [0,10, 10,10, 5,0, 0,10] }; |
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