/**
* Determines if the damage region affects a particular tree node, looking only at those tokens
* that actually belong to the node and not to its children.
*/
protected boolean isDamageTreeNode(ISimpleTerm tree, boolean isOriginalTree, int skippedChars) {
IToken current = findLeftMostLayoutToken(getLeftToken(tree));
IToken last = findRightMostLayoutToken(getRightToken(tree));
if (current != null && last != null) {
if (!isDamagedRange(
current.getStartOffset(), last.getEndOffset(), isOriginalTree, skippedChars))
return false;
Iterator<ISimpleTerm> iterator = tryGetListIterator(tree);
for (int i = 0, max = tree.getSubtermCount(); i < max; i++) {
ISimpleTerm child = iterator == null ? tree.getSubterm(i) : iterator.next();
IToken childLeft = findLeftMostLayoutToken(getLeftToken(child));
IToken childRight = findRightMostLayoutToken(getRightToken(child));
if (childLeft != null && childRight != null) {
if (childLeft.getIndex() > current.getIndex()
&& isDamagedRange(
current.getEndOffset() + 1,
childLeft.getStartOffset() - 1,
isOriginalTree,
skippedChars)) {
return true;
}
current = childRight;
}
}
return isDamagedRange(
current.getEndOffset() + 1, last.getEndOffset(), isOriginalTree, skippedChars);
} else {
return false;
}
}
/**
* Gets all non-list tree nodes from a tree that are in the damage region according to {@link
* #isDamageTreeNode}. Tries to take the innermost {@link #incrementalSorts} tree node where
* possible instead of taking an inner non-incremental tree node.
*
* @param tree Current tree node
* @param results Found tree nodes
* @param isOriginalTree Whether the tree is the input tree of the incremental parser
* @param skippedChars See {@link IncrementalInputBuilder#getLastSkippedCharsBeforeDamage()}.
* @param outerIncrementalNode The innermost ancestor of the current tree that is in {@link
* #incrementalSorts}.
* @return the last ancestral tree node added to the list
*/
private ISimpleTerm getDamageRegionTreeNodes(
ISimpleTerm tree,
List<ISimpleTerm> results,
boolean isOriginalTree,
int skippedChars,
ISimpleTerm outerIncrementalNode) {
if (incrementalSorts.isIncrementalNode(tree)) outerIncrementalNode = tree;
if (!tree.isList() // prefer adding list children
&& isDamageTreeNode(tree, isOriginalTree, skippedChars))
return addDamageRegionTreeNode(tree, results, outerIncrementalNode);
// Recurse
boolean addedChild = false;
Iterator<ISimpleTerm> iterator = tryGetListIterator(tree);
for (int i = 0, max = tree.getSubtermCount(); i < max; i++) {
ISimpleTerm child = iterator == null ? tree.getSubterm(i) : iterator.next();
ISimpleTerm addedAncestor =
getDamageRegionTreeNodes(
child, results, isOriginalTree, skippedChars, outerIncrementalNode);
if (addedAncestor != null && addedAncestor == outerIncrementalNode) return addedAncestor;
addedChild = true;
}
if (!addedChild
&& tree.isList() // add list (outerIncrementalNode), if we must
&& isDamageTreeNode(tree, isOriginalTree, skippedChars))
return addDamageRegionTreeNode(tree, results, outerIncrementalNode);
return null;
}
private void bindAstNode(ISimpleTerm node, int tokenIndex, int endTokenIndex) {
assert getTokenizer(node) == this;
int tokenCount = getTokenCount();
// Set ast node for spaces between children and recursively for children
Iterator<ISimpleTerm> iterator = SimpleTermVisitor.tryGetListIterator(node);
for (int i = 0, max = node.getSubtermCount(); i < max; i++) {
ISimpleTerm child = iterator == null ? node.getSubterm(i) : iterator.next();
int childStart = getLeftToken(child).getIndex();
int childEnd = getRightToken(child).getIndex();
while (tokenIndex < childStart && tokenIndex < tokenCount) {
Token token = getTokenAt(tokenIndex++);
token.setAstNode(node);
}
bindAstNode(child, childStart, childEnd);
tokenIndex = childEnd + 1;
}
// Set ast node for tokens after children
while (tokenIndex <= endTokenIndex && tokenIndex < tokenCount) {
Token token = getTokenAt(tokenIndex++);
token.setAstNode(node);
}
}
