mediawiki-extensions-Visual.../modules/ve/ve.BranchNode.js

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/**
* VisualEditor BranchNode class.
*
* @copyright 2011-2012 VisualEditor Team and others; see AUTHORS.txt
* @license The MIT License (MIT); see LICENSE.txt
*/
/**
* Mixin for branch nodes.
*
* Branch nodes are immutable, which is why there are no methods for adding or removing children.
* DataModel classes will add this functionality, and other subclasses will implement behavior that
* mimcs changes made to data model nodes.
*
* @class
* @abstract
* @constructor
* @param {ve.Node[]} children Array of children to add
*/
ve.BranchNode = function( children ) {
this.children = ve.isArray( children ) ? children : [];
};
/**
* Checks if this node has child nodes.
*
* @method
* @see {ve.Node.prototype.hasChildren}
* @returns {Boolean} Whether this node has children
*/
ve.BranchNode.prototype.hasChildren = function() {
return true;
};
/**
* Gets a list of child nodes.
*
* @method
* @returns {ve.Node[]} List of child nodes
*/
ve.BranchNode.prototype.getChildren = function() {
return this.children;
};
/**
* Gets the index of a given child node.
*
* @method
* @param {ve.dm.Node} node Child node to find index of
* @returns {Integer} Index of child node or -1 if node was not found
*/
ve.BranchNode.prototype.indexOf = function( node ) {
return ve.inArray( node, this.children );
};
/**
* Sets the root node this node is a descendent of.
*
* @method
* @see {ve.Node.prototype.setRoot}
* @param {ve.Node} root Node to use as root
*/
ve.BranchNode.prototype.setRoot = function( root ) {
if ( root === this.root ) {
// Nothing to do, don't recurse into all descendants
return;
}
this.root = root;
for ( var i = 0; i < this.children.length; i++ ) {
this.children[i].setRoot( root );
}
};
/**
* Sets the document this node is a part of.
*
* @method
* @see {ve.Node.prototype.setDocument}
* @param {ve.Document} root Node to use as root
*/
ve.BranchNode.prototype.setDocument = function( doc ) {
if ( doc === this.doc ) {
// Nothing to do, don't recurse into all descendants
return;
}
this.doc = doc;
for ( var i = 0; i < this.children.length; i++ ) {
this.children[i].setDocument( doc );
}
};
/**
* Gets the node at a given offset.
*
* This method is pretty expensive. If you need to get different slices of the same content, get
* the content first, then slice it up locally.
*
* TODO: Rewrite this method to not use recursion, because the function call overhead is expensive
*
* @method
* @param {Integer} offset Offset get node for
* @param {Boolean} [shallow] Do not iterate into child nodes of child nodes
* @returns {ve.Node|null} Node at offset, or null if non was found
*/
ve.BranchNode.prototype.getNodeFromOffset = function( offset, shallow ) {
if ( offset === 0 ) {
return this;
}
// TODO a lot of logic is duplicated in selectNodes(), abstract that into a traverser or something
if ( this.children.length ) {
var nodeOffset = 0,
nodeLength,
childNode;
for ( var i = 0, length = this.children.length; i < length; i++ ) {
childNode = this.children[i];
if ( offset === nodeOffset ) {
// The requested offset is right before childNode,
// so it's not inside any of this's children, but inside this
return this;
}
nodeLength = childNode.getOuterLength();
if ( offset >= nodeOffset && offset < nodeOffset + nodeLength ) {
if ( !shallow && childNode.hasChildren() && childNode.getChildren().length ) {
return this.getNodeFromOffset.call( childNode, offset - nodeOffset - 1 );
} else {
return childNode;
}
}
nodeOffset += nodeLength;
}
if ( offset === nodeOffset ) {
// The requested offset is right before this.children[i],
// so it's not inside any of this's children, but inside this
return this;
}
}
return null;
};
/**
* Gets the content offset of a node.
*
* TODO: Rewrite this method to not use recursion, because the function call overhead is expensive
*
* @method
* @param {ve.Node} node Node to get offset of
* @returns {Integer} Offset of node or -1 of node was not found
*/
ve.BranchNode.prototype.getOffsetFromNode = function( node ) {
if ( node === this ) {
return 0;
}
if ( this.children.length ) {
var offset = 0,
childNode;
for ( var i = 0, length = this.children.length; i < length; i++ ) {
childNode = this.children[i];
if ( childNode === node ) {
return offset;
}
if ( childNode.canHaveChildren() && childNode.getChildren().length ) {
var childOffset = this.getOffsetFromNode.call( childNode, node );
if ( childOffset !== -1 ) {
return offset + 1 + childOffset;
}
}
offset += childNode.getOuterLength();
}
}
return -1;
};
/**
* Traverse leaf nodes depth first.
*
* Callback functions are expected to accept a node and index argument. If a callback returns false,
* iteration will stop.
*
* @param {Function} callback Function to execute for each leaf node
* @param {ve.Node} [from] Node to start at. Must be a descendant of this node
* @param {Boolean} [reverse] Whether to iterate backwards
*/
ve.BranchNode.prototype.traverseLeafNodes = function( callback, from, reverse ) {
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// Stack of indices that lead from this to node
var indexStack = [],
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// Node whose children we're currently traversing
node = this,
// Index of the child node we're currently visiting
index = reverse ? node.children.length - 1 : 0,
// Shortcut for node.children[index]
childNode,
// Result of the last invocation of the callback
callbackResult,
// Variables for the loop that builds indexStack if from is specified
n, p, i;
if ( from !== undefined ) {
// Reverse-engineer the index stack by starting at from and
// working our way up until we reach this
n = from;
while ( n !== this ) {
p = n.getParent();
if ( !p ) {
// n is a root node and we haven't reached this
// That means from isn't a descendant of this
throw "from parameter passed to traverseLeafNodes() must be a descendant";
}
// Find the index of n in p
i = p.indexOf( n );
if ( i === -1 ) {
// This isn't supposed to be possible
throw "Tree corruption detected: node isn't in its parent's children array";
}
indexStack.push( i );
// Move up
n = p;
}
// We've built the indexStack in reverse order, so reverse it
indexStack = indexStack.reverse();
// Set up the variables such that from will be visited next
index = indexStack.pop();
node = from.getParent(); // from is a descendant of this so its parent exists
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// If we're going in reverse, then we still need to visit from if it's
// a leaf node, but we should not descend into it
// So if from is not a leaf node, skip it now
if ( reverse && from.canHaveChildren() ) {
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index--;
}
}
while ( true ) {
childNode = node.children[index];
if ( childNode === undefined ) {
if ( indexStack.length > 0 ) {
// We're done traversing the current node, move back out of it
node = node.getParent();
index = indexStack.pop();
// Move to the next child
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index += reverse ? -1 : 1;
continue;
} else {
// We can't move up any more, so we're done
return;
}
}
if ( childNode.canHaveChildren() ) {
// Descend into this node
node = childNode;
// Push our current index onto the stack
indexStack.push( index );
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// Set the current index to the first element we're visiting
index = reverse ? node.children.length - 1 : 0;
} else {
// This is a leaf node, visit it
callbackResult = callback( childNode ); // TODO what is index?
if ( callbackResult === false ) {
// The callback is telling us to stop
return;
}
// Move to the next child
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index += reverse ? -1 : 1;
}
}
};