/** * Generic document. * * @class * @constructor * @param model {ve.Node} Model to observe */ ve.Document = function( documentNode ) { // Properties this.documentNode = documentNode; }; /* Methods */ /** * Gets the root of the document's node tree. * * @method * @returns {ve.Node} Root of node tree */ ve.Document.prototype.getDocumentNode = function() { return this.documentNode; }; /** * Gets a list of nodes and the ranges within them that a selection of the document covers. * * @method * @param {ve.Range} range Range within document to select nodes * @param {String} [mode='leaves'] Type of selection to perform * 'leaves': Return all leaf nodes in the given range (descends all the way down) * 'siblings': Return a set of adjacent siblings covered by the range (descends as long as the * range is in a single node) * @returns {Array} List of objects describing nodes in the selection and the ranges therein * 'node': Reference to a ve.dm.Node * 'range': ve.Range, missing if the entire node is covered * 'index': Index of the node in its parent, missing if node has no parent * 'indexInNode': If range is a zero-length range between two children of node, * this is set to the index of the child following range (or to * node.children.length+1 if range is between the last child and * the end). Missing in all other cases * 'nodeRange': Range covering the inside of the entire node * @throws 'Invalid start offset' if range.start is out of range * @throws 'Invalid end offset' if range.end is out of range */ ve.Document.prototype.selectNodes = function( range, mode ) { var doc = this.documentNode, retval = [], start = range.start, end = range.end, stack = [ { // Node we are currently stepping through // Note each iteration visits a child of node, not node itself 'node': doc, // Index of the child in node we're visiting 'index': 0, // First offset inside node 'startOffset': 0 } ], node, prevNode, nextNode, left, right, currentFrame = stack[0], parentFrame, startInside, endInside, startBetween, endBetween, startFound = false, nodeRange, isWrapped; mode = mode || 'leaves'; if ( mode !== 'leaves' && mode !== 'siblings' ) { throw 'Invalid mode: ' + mode; } if ( start < 0 || start > doc.getLength() ) { throw 'Invalid start offset: ' + start; } if ( end < 0 || end > doc.getLength() ) { throw 'Invalid end offset: ' + end; } if ( !doc.children || doc.children.length === 0 ) { // Document has no children. This is weird nodeRange = new ve.Range( 0, doc.getLength() ); return [ { 'node': doc, 'range': new ve.Range( start, end ), 'index': 0, 'nodeRange': nodeRange, 'nodeOuterRange': nodeRange } ]; } // TODO maybe we could find the start more efficiently using the offset map left = doc.children[0].isWrapped() ? 1 : 0; do { node = currentFrame.node.children[currentFrame.index]; prevNode = currentFrame.node.children[currentFrame.index - 1]; nextNode = currentFrame.node.children[currentFrame.index + 1]; right = left + node.getLength(); // Is the start inside node? startInside = start >= left && start <= right; // Is the end inside node? endInside = end >= left && end <= right; // Does the node have wrapping elements around it isWrapped = node.isWrapped(); // Is the start between prevNode and node or between the parent's opening and node? startBetween = isWrapped ? start == left - 1 : start == left; // Is the end between node and nextNode or between node and the parent's closing? endBetween = isWrapped ? end == right + 1 : end == right; if ( start == end && ( startBetween || endBetween ) && node.isWrapped() ) { // Empty range in the parent, outside of any child nodeRange = new ve.Range( currentFrame.startOffset, currentFrame.startOffset + currentFrame.node.getLength() ); isWrapped = currentFrame.node.isWrapped(); retval = [ { 'node': currentFrame.node, 'indexInNode': currentFrame.index + ( endBetween ? 1 : 0 ), 'range': new ve.Range( start, end ), 'nodeRange': nodeRange, 'nodeOuterRange': new ve.Range( nodeRange.start - isWrapped, nodeRange.start + isWrapped ) } ]; parentFrame = stack[stack.length - 2]; if ( parentFrame ) { retval[0].index = parentFrame.index; } } else if ( startBetween ) { // start is between the previous sibling and node // so the selection covers all of node and possibly more if ( mode == 'leaves' && node.children && node.children.length ) { // Descend into node if ( node.children[0].isWrapped() ) { left++; } currentFrame = { 'node': node, 'index': 0, 'startOffset': left }; stack.push( currentFrame ); startFound = true; continue; } else if ( !endInside ) { // All of node is covered retval.push( { 'node': node, // no 'range' because the entire node is covered 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ); startFound = true; } else { // Part of node is covered return [ { 'node': node, 'range': new ve.Range( start, end ), 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ]; } } else if ( startInside && endInside ) { if ( node.children && node.children.length ) { // Descend into node // If the first child of node has an opening, skip over it if ( node.children[0].isWrapped() ) { left++; } currentFrame = { 'node': node, 'index': 0, 'startOffset': left }; stack.push( currentFrame ); continue; } else { // node is a leaf node and the range is entirely inside it return [ { 'node': node, 'range': new ve.Range( start, end ), 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ]; } } else if ( startInside ) { if ( mode == 'leaves' && node.children && node.children.length ) { // node is a branch node and the start is inside it // Descend into it if ( node.children[0].isWrapped() ) { left++; } currentFrame = { 'node': node, 'index': 0, 'startOffset': left }; stack.push( currentFrame ); continue; } else { // node is a leaf node and the start is inside it // Add to retval and keep going retval.push( { 'node': node, 'range': new ve.Range( start, right ), 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ); startFound = true; } } else if ( endBetween ) { // end is between node and the next sibling // start is not inside node, so the selection covers // all of node, then ends //retval.push( { 'node': node } ); if ( mode == 'leaves' && node.children && node.children.length ) { // Descend into node if ( node.children[0].isWrapped() ) { left++; } currentFrame = { 'node': node, 'index': 0, 'startOffset': left }; stack.push( currentFrame ); continue; } else { // All of node is covered retval.push( { 'node': node, // no 'range' because the entire node is covered 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ); return retval; } } else if ( endInside ) { if ( mode == 'leaves' && node.children && node.children.length ) { // node is a branch node and the end is inside it // Descend into it if ( node.children[0].isWrapped() ) { left++; } currentFrame = { 'node': node, 'index': 0, 'startOffset': left }; stack.push( currentFrame ); continue; } else { // node is a leaf node and the end is inside it // Add to retval and return retval.push( { 'node': node, 'range': new ve.Range( left, end ), 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ); return retval; } } else if ( startFound ) { // Neither the start nor the end is inside node, but we found the start earlier, // so node must be between the start and the end // Add the entire node, so no range property //retval.push( { 'node': node } ); if ( mode == 'leaves' && node.children && node.children.length ) { // Descend into node if ( node.children[0].isWrapped() ) { left++; } currentFrame = { 'node': node, 'index': 0, 'startOffset': left }; stack.push( currentFrame ); continue; } else { // All of node is covered retval.push( { 'node': node, // no 'range' because the entire node is covered 'index': currentFrame.index, 'nodeRange': new ve.Range( left, right ), 'nodeOuterRange': new ve.Range( left - isWrapped, right + isWrapped ) } ); } } // Move to the next node if ( nextNode ) { // The next node exists // Advance the index; the start of the next iteration will essentially // do node = nextNode; currentFrame.index++; // Advance to the first offset inside nextNode left = right + // Skip over node's closing, if present ( node.isWrapped() ? 1 : 0 ) + // Skip over nextNode's opening, if present ( nextNode.isWrapped() ? 1 : 0 ); } else { // There is no next node, move up the stack until there is one left = right + // Skip over node's closing, if present ( node.isWrapped() ? 1 : 0 ); while ( !nextNode ) { stack.pop(); if ( stack.length === 0 ) { // This shouldn't be possible return retval; } currentFrame = stack[stack.length - 1]; currentFrame.index++; nextNode = currentFrame.node.children[currentFrame.index]; // Skip over the parent node's closing // (this is present for sure, because the parent has children) left++; } // Skip over nextNode's opening if present if ( nextNode.isWrapped() ) { left++; } } } while ( end >= left ); return retval; };