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Event-driven lists for dynamically filtered and sorted tables
/* Glazed Lists (c) 2003-2006 */
/* http://publicobject.com/glazedlists/ publicobject.com,*/
/* O'Dell Engineering Ltd.*/
package ca.odell.glazedlists.impl.adt;
/**
* A BarcodeNode models a node in an Barcode. This class
* does the bulk of the heavy lifting for Barcode.
*
* @author Kevin Maltby
*
*/
final class BarcodeNode {
/** the parent node */
BarcodeNode parent;
/** the tree that this node is a member of */
private Barcode host;
/** the left and right child nodes */
BarcodeNode left = null;
BarcodeNode right = null;
/** the size of the black portion of the left and right subtrees */
private int blackLeftSize = 0;
private int blackRightSize = 0;
/** the total size of the left and right subtrees */
private int treeLeftSize = 0;
private int treeRightSize = 0;
/** the amount of empty space that precedes this node */
int whiteSpace = 0;
/** the number of values represented by this node */
int rootSize = 1;
/** the height of this subtree */
private int height = 1;
/**
* Creates a new BarcodeNode with the specified parent node and host tree.
*/
private BarcodeNode(Barcode host, BarcodeNode parent) {
this.host = host;
this.parent = parent;
}
/**
* This is a convenience constructor for creating a new BarcodeNode
* with a given number of values and amount of preceding empty space.
*/
BarcodeNode(Barcode host, BarcodeNode parent, int values, int whiteSpace) {
this(host, parent);
this.whiteSpace = whiteSpace;
this.rootSize = values;
}
/**
* Returns the size of the subtree rooted at this node
*/
int size() {
return treeLeftSize + whiteSpace + rootSize + treeRightSize;
}
/**
* Returns the size of the black portion of the subtree rooted at this
*/
int blackSize() {
return blackLeftSize + rootSize + blackRightSize;
}
/**
* Returns the size of the white portion of the subtree rooted at this
*/
int whiteSize() {
return (treeLeftSize - blackLeftSize) + whiteSpace + (treeRightSize - blackRightSize);
}
/**
* Inserts multiple values into the host tree
*/
void insertBlack(int index, int length) {
int localIndex = index - treeLeftSize;
// Recurse to the Left adjusting sizes as you go
if(localIndex < 0) {
blackLeftSize += length;
treeLeftSize += length;
left.insertBlack(index, length);
// Recurse to the Right adjusting sizes as you go
} else if(localIndex > whiteSpace + rootSize) {
blackRightSize += length;
treeRightSize += length;
right.insertBlack(localIndex - whiteSpace - rootSize, length);
// The new values should be compressed into this node
} else if(localIndex == whiteSpace + rootSize) {
rootSize += length;
// Insert in the middle of the empty space
} else if(localIndex < whiteSpace) {
whiteSpace -= localIndex;
blackLeftSize += length;
treeLeftSize += localIndex + length;
if(left == null) {
left = new BarcodeNode(host, this, length, localIndex);
ensureAVL();
} else {
left.insertBlackAtEnd(length, localIndex);
}
// Insert within this node
} else {
rootSize += length;
}
}
/**
* Inserts a value at the end of the tree rooted at this.
*/
void insertBlackAtEnd(int values, int leadingWhite) {
// Recurse to the right
if(right != null) {
blackRightSize += values;
treeRightSize += values + leadingWhite;
right.insertBlackAtEnd(values, leadingWhite);
// Insert on the right
} else {
if(leadingWhite == 0) {
rootSize += values;
} else {
blackRightSize += values;
treeRightSize += values + leadingWhite;
right = new BarcodeNode(host, this, values, leadingWhite);
ensureAVL();
}
}
}
/**
* Inserts multiple null values as empty space in the host tree.
*/
void insertWhite(int index, int length) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) {
treeLeftSize += length;
left.insertWhite(index, length);
// Recurse to the Right
} else if(localIndex > whiteSpace + rootSize - 1) {
treeRightSize += length;
right.insertWhite(localIndex - whiteSpace - rootSize, length);
// Insert in the whitespace for this node
} else if(localIndex <= whiteSpace) {
whiteSpace += length;
// Insert within this node
} else {
localIndex -= whiteSpace;
int movingRoot = rootSize - localIndex;
rootSize = localIndex;
blackRightSize += movingRoot;
treeRightSize += movingRoot + length;
if(right == null) {
right = new BarcodeNode(host, this, movingRoot, length);
ensureAVL();
} else {
BarcodeNode node = new BarcodeNode(host, null, movingRoot, length);
right.moveToSmallest(node);
}
}
}
/**
* Moves a given node to be the smallest node in the subtree rooted at
* this.
*/
private void moveToSmallest(BarcodeNode movingNode) {
// Recurse to the left
if(left != null) {
blackLeftSize += movingNode.rootSize;
treeLeftSize += movingNode.whiteSpace + movingNode.rootSize;
left.moveToSmallest(movingNode);
// Add the node as a left child of this
} else {
// This node will be compressed now
if(whiteSpace == 0) {
rootSize += movingNode.rootSize;
whiteSpace += movingNode.whiteSpace;
movingNode.clear();
// Add the moving node on the left
} else {
blackLeftSize += movingNode.rootSize;
treeLeftSize += movingNode.whiteSpace + movingNode.rootSize;
movingNode.parent = this;
left = movingNode;
ensureAVL();
}
}
}
/**
* Gets the white-centric index from the given list index or returns -1
* if that list index has a value of Barcode.BLACK
.
*/
int getWhiteIndex(int index) {
return getWhiteIndex(index, 0);
}
private int getWhiteIndex(int index, int accumulation) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) return left.getWhiteIndex(index, accumulation);
// Recurse to the Right
else if(localIndex > whiteSpace + rootSize - 1) {
accumulation += (treeLeftSize - blackLeftSize) + whiteSpace;
return right.getWhiteIndex(localIndex - whiteSpace - rootSize, accumulation);
// Get the white index from this node
} else if(localIndex < whiteSpace) return accumulation + (treeLeftSize - blackLeftSize) + localIndex;
// Get the white index from the black portion of this node
else return -1;
}
/**
* Gets the black-centric index from the given list index or returns -1
* if that list index has a value of Barcode.WHITE
.
*/
int getBlackIndex(int index) {
return getBlackIndex(index, 0);
}
private int getBlackIndex(int index, int accumulation) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) return left.getBlackIndex(index, accumulation);
// Recurse to the Right
else if(localIndex > whiteSpace + rootSize - 1) {
return right.getBlackIndex(localIndex - whiteSpace - rootSize, accumulation + blackLeftSize + rootSize);
// Get the black index from the white portion of this node
} else if(localIndex < whiteSpace) return -1;
// Get the black index from this node
else return accumulation + blackLeftSize + localIndex - whiteSpace;
}
/**
* Gets the white-centric index from the given list index.
*
* @param lead true for an index with a value of Barcode.BLACK to return
* the white-centric index of the previous white value in the Barcode.
* False for an index with a value of Barcode.BLACK to return
* the white-centric index of the next white value in the Barcode.
*/
public int getWhiteIndex(int index, boolean lead) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) return left.getWhiteIndex(index, lead);
// Recurse to the Right
else if(localIndex > whiteSpace + rootSize - 1) {
return right.getWhiteIndex(localIndex - whiteSpace - rootSize, lead) + treeLeftSize - blackLeftSize + whiteSpace;
// Get the white index from within this node
} else if(localIndex < whiteSpace) {
return treeLeftSize - blackLeftSize + localIndex;
// Get the white index based on lead
} else {
if(lead) return treeLeftSize - blackLeftSize + whiteSpace - 1;
return treeLeftSize - blackLeftSize + whiteSpace;
}
}
/**
* Gets the black-centric index from the given list index.
*
* @param lead true for an index with a value of Barcode.WHITE to return
* the black-centric index of the previous black value in the Barcode.
* False for an index with a value of Barcode.WHITE to return
* the black-centric index of the next black value in the Barcode.
*/
public int getBlackIndex(int index, boolean lead) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) return left.getBlackIndex(index, lead);
// Recurse to the Right
else if(localIndex > whiteSpace + rootSize - 1) {
return right.getBlackIndex(localIndex - whiteSpace - rootSize, lead) + blackLeftSize + rootSize;
// Get the black index based on lead
} else if(localIndex < whiteSpace) {
if(lead) return blackLeftSize - 1;
return blackLeftSize;
// Get the black index at this node
} else return blackLeftSize + localIndex - whiteSpace;
}
/**
* Gets the list index from a given white-centric index.
*/
public int getIndexByWhiteIndex(int whiteIndex) {
int localIndex = whiteIndex - (treeLeftSize - blackLeftSize);
// Recurse to the Left
if(localIndex < 0) return left.getIndexByWhiteIndex(whiteIndex);
// Recurse to the Right
else if(localIndex >= whiteSpace) {
return right.getIndexByWhiteIndex(localIndex - whiteSpace)
+ treeLeftSize + whiteSpace + rootSize;
// Get the list index from this node
} else return treeLeftSize + localIndex;
}
/**
* Gets the list index from a given black-centric index.
*/
public int getIndexByBlackIndex(int blackIndex) {
int localIndex = blackIndex - blackLeftSize;
// Recurse to the Left
if(localIndex < 0) return left.getIndexByBlackIndex(blackIndex);
// Recurse to the Right
else if(localIndex >= rootSize) {
return right.getIndexByBlackIndex(localIndex - rootSize)
+ treeLeftSize + whiteSpace + rootSize;
// Get the list index from this node
} else return treeLeftSize + whiteSpace + localIndex;
}
/**
* Gets the sequence relative index given a white-centric index.
*/
public int getWhiteSequenceIndex(int whiteIndex) {
int localIndex = whiteIndex - (treeLeftSize - blackLeftSize);
// Recurse to the Left
if(localIndex < 0) return left.getWhiteSequenceIndex(whiteIndex);
// Recurse to the Right
else if(localIndex >= whiteSpace) {
return right.getWhiteSequenceIndex(localIndex - whiteSpace);
// once the recursion is done you have the relative index
} else return localIndex;
}
/**
* This method exists for CollectionList which needs a way to call
* getBlackIndex(index, true) with a white-centric index.
*/
public int getBlackBeforeWhite(int whiteIndex) {
int localIndex = whiteIndex - (treeLeftSize - blackLeftSize);
// Recurse to the Left
if(localIndex < 0) return left.getBlackBeforeWhite(whiteIndex);
// Recurse to the Right
else if(localIndex >= whiteSpace) {
return right.getBlackBeforeWhite(localIndex - whiteSpace) + blackLeftSize + rootSize;
// Get the black index before this node
} else {
return blackLeftSize - 1;
}
}
/**
* Finds a sequence of the given colour that is at least size elements
* in length.
*
* @param size the minimum size of a matching sequence.
*
* @return The natural index of the first element in the sequence or -1 if
* no sequences of that length exist.
*/
public int findSequenceOfMinimumSize(int size, Object colour) {
return findFirstFitSequence(size, colour, 0);
}
/**
* The depth-first, FIRST FIT implementation.
*/
private int findFirstFitSequence(int size, Object colour, int accumulation) {
int result = -1;
// Recurse to the Left
if(left != null) {
result = left.findFirstFitSequence(size, colour, accumulation);
}
// Inspect this node
if(result == -1) {
// Looking for a WHITE sequence
if(colour == Barcode.WHITE && size <= whiteSpace) {
return accumulation + treeLeftSize;
// Looking for a BLACK sequence
} else if(colour == Barcode.BLACK && size <= rootSize) {
return accumulation + treeLeftSize + whiteSpace;
}
}
// Recurse to the Right
if(result == -1 && right != null) {
result = right.findFirstFitSequence(size, colour, accumulation + treeLeftSize + whiteSpace + rootSize);
}
return result;
}
/**
* Sets the values from index to index + length.
*/
void set(int index, Object value, int length) {
if(length == 1) setBaseCase(index, index, value);
else set(index, index, value, length);
}
private void set(int absoluteIndex, int localIndex, Object value, int length) {
int localizedIndex = localIndex - treeLeftSize;
// Recurse to the Left
if(localizedIndex < 0) {
left.set(absoluteIndex, localIndex, value, length);
// Recurse to the Right
} else if(localizedIndex > whiteSpace + rootSize - 1) {
right.set(absoluteIndex, localizedIndex - whiteSpace - rootSize, value, length);
// Set values on this node to white
} else if(value == Barcode.WHITE) {
setWhite(absoluteIndex, localizedIndex, length);
// Set values on this node to black
} else {
setBlack(absoluteIndex, localizedIndex, length);
}
}
void setWhite(int absoluteIndex, int localIndex, int length) {
int endIndex = localIndex + length - 1;
// Set only whitespace so no change at all
if(endIndex < whiteSpace) {
// Do Nothing
// Set only within the black
} else if(localIndex > whiteSpace - 1) {
int rootChange = Math.min(length, whiteSpace + rootSize - localIndex);
// This node will be removed
if(rootSize == rootChange) {
whiteSpace += rootChange;
rootSize = 0;
correctSizes(-rootChange, 0);
unlink(absoluteIndex - localIndex);
// Update root and add white space
} else {
rootSize -= rootChange;
if(localIndex < whiteSpace + rootSize) {
correctSizes(-rootChange, 0);
insertWhite(localIndex + treeLeftSize, rootChange);
} else {
correctSizes(-rootChange, -rootChange);
host.addWhite(absoluteIndex, rootChange);
}
}
// Set is larger than just this node
if(rootChange != length) {
host.remove(absoluteIndex + rootChange, length - rootChange);
host.addWhite(absoluteIndex + rootChange, length - rootChange);
}
// Set both black and white
} else if(localIndex < whiteSpace + 1 && endIndex < whiteSpace + rootSize) {
int rootChange = Math.min(length, whiteSpace + rootSize - localIndex) + (localIndex - whiteSpace);
rootSize -= rootChange;
whiteSpace += rootChange;
correctSizes(-rootChange, 0);
// Set this entire node to white
} else {
whiteSpace += rootSize;
int localLength = whiteSpace - localIndex;
unlink(absoluteIndex - localIndex);
if(localLength != length) {
host.remove(absoluteIndex + localLength, length - localLength);
host.addWhite(absoluteIndex + localLength, length - localLength);
}
}
}
void setBlack(int absoluteIndex, int localIndex, int length) {
int endIndex = localIndex + length - 1;
int localLength = Math.min(length, whiteSpace + rootSize - localIndex);
// Set only black so no change at this node
if(localIndex > whiteSpace - 1) {
// Do Nothing
// Set some or all white to black
} else if(endIndex > whiteSpace - 1) {
int whiteChange = whiteSpace - localIndex;
rootSize += whiteChange;
whiteSpace -= whiteChange;
correctSizes(whiteChange, 0);
compressNode(absoluteIndex - localIndex);
// Set within the whitespace
} else {
whiteSpace -= length;
correctSizes(0, -length);
host.addBlack(absoluteIndex, length);
compressNode(absoluteIndex - localIndex);
}
// Remove/Add if the length spills over to another node
if(localLength != length) {
host.remove(absoluteIndex + localLength, length - localLength);
host.addBlack(absoluteIndex + localLength, length - localLength);
}
}
/**
* Sets the value of the element at a given index.
*/
private void setBaseCase(int absoluteIndex, int index, Object value) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) {
left.setBaseCase(absoluteIndex, index, value);
// Recurse to the Right
} else if(localIndex > whiteSpace + rootSize) {
right.setBaseCase(absoluteIndex, localIndex - whiteSpace - rootSize, value);
// Edge case where leading white moves to this
} else if(localIndex == whiteSpace + rootSize) {
// Add the new value to this root
if(value != Barcode.WHITE) {
rootSize++;
treeRightSize--;
correctSizes(1, 0);
right.setFirstNullToTrue(absoluteIndex, localIndex - whiteSpace - rootSize + 1);
}
// Set a value in the middle of the white space
} else if(localIndex < whiteSpace) {
if(value == Barcode.WHITE) return;
whiteSpace--;
correctSizes(1, 0);
insertBlack(index, 1);
compressNode(absoluteIndex);
// Set a value at the leading edge of this node
} else if(localIndex == whiteSpace) {
if(value == Barcode.WHITE) {
whiteSpace++;
rootSize--;
correctSizes(-1, 0);
if(rootSize == 0) unlink(absoluteIndex - localIndex);
}
// Set a value at the trailing edge of this node
} else if(localIndex == whiteSpace + rootSize - 1) {
if(value == Barcode.WHITE) {
rootSize--;
if(right != null) {
treeRightSize++;
right.insertWhite(localIndex - whiteSpace - rootSize, 1);
correctSizes(-1, 0);
} else if(parent != null && parent.left == this) {
parent.whiteSpace++;
parent.treeLeftSize--;
parent.correctSizes(true, -1, 0);
} else {
correctSizes(-1, -1);
host.addWhite(absoluteIndex, 1);
}
}
// Set the value in this node
} else {
if(value == Barcode.WHITE) {
rootSize--;
correctSizes(-1, 0);
insertWhite(index, 1);
}
}
}
/**
* A helper method for a base-case condition where the first null on a node
* is set to a value. This value is moved to the node that it is compressed
* into before this method is called. This method may result in further
* compression.
*/
private void setFirstNullToTrue(int absoluteIndex, int index) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) {
treeLeftSize--;
left.setFirstNullToTrue(absoluteIndex, index);
// Recurse to the Right
} else if(localIndex > whiteSpace + rootSize - 1) {
treeRightSize--;
right.setFirstNullToTrue(absoluteIndex, localIndex - whiteSpace - rootSize);
// Affect this node
} else {
whiteSpace--;
compressNode(absoluteIndex);
}
}
/**
* Removes the values from the given index to index + length
*/
void remove(int index, int length) {
if(length == 1) removeBaseCase(index, index);
else remove(index, index, length);
}
private void remove(int absoluteIndex, int index, int length) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) {
left.remove(absoluteIndex, index, length);
// Recurse to the Right
} else if(localIndex > whiteSpace + rootSize - 1) {
right.remove(absoluteIndex, localIndex - whiteSpace - rootSize, length);
} else {
// Trim the length to only affect this node
length = Math.min(localIndex + length, whiteSpace + rootSize) - localIndex;
int endIndex = localIndex + length - 1;
// Remove white and possibly some, but not all, black
if(localIndex < whiteSpace && endIndex < whiteSpace + rootSize) {
int whiteChange = Math.min(whiteSpace - localIndex, length);
int blackChange = Math.max(endIndex - whiteSpace + 1, 0);
whiteSpace -= whiteChange;
rootSize -= blackChange;
correctSizes(-blackChange, -(whiteChange + blackChange));
compressNode(absoluteIndex - localIndex);
// Remove only black
} else if(localIndex > whiteSpace - 1) {
// Remove all black so unlink this node
if(length == rootSize) {
unlink(absoluteIndex - localIndex);
// Only remove some of the black
} else {
rootSize -= length;
correctSizes(-length, -length);
}
// Remove this entire node
} else {
int whiteChange = whiteSpace;
int blackChange = rootSize;
whiteSpace = 0;
rootSize = 0;
correctSizes(-blackChange, -(whiteChange + blackChange));
unlink(absoluteIndex - localIndex);
}
}
}
/**
* Removes the single value at a given index.
*/
void removeBaseCase(int absoluteIndex, int index) {
int localIndex = index - treeLeftSize;
// Recurse to the Left
if(localIndex < 0) {
treeLeftSize--;
left.removeBaseCase(absoluteIndex, index);
// Recurse to the Right
} else if(localIndex > whiteSpace + rootSize - 1) {
treeRightSize--;
right.removeBaseCase(absoluteIndex, localIndex - whiteSpace - rootSize);
// Remove from the middle of the white space
} else if(localIndex < whiteSpace) {
whiteSpace--;
compressNode(absoluteIndex);
// Remove from the black portion of this node
} else {
rootSize--;
if(rootSize == 0) {
rootSize = 1;
unlink(absoluteIndex - localIndex, false);
} else correctSizes(-1, 0);
}
}
/**
* Unlinks this node from the tree and clears it.
*/
private void unlink(int absoluteIndex) {
unlink(absoluteIndex, true);
}
private void unlink(int absoluteIndex, boolean consistent) {
// Two children exist
if(right != null && left != null) {
if(rootSize != 0) correctSizes(-rootSize, -rootSize, consistent);
unlinkWithTwoChildren();
// Only a right child exists
} else if(right != null) {
unlinkWithRightChild(consistent);
// A left child or no child exists, which are handled almost the same way
} else {
BarcodeNode replacement = null;
// Only a left child exists
if(left != null) {
replacement = left;
replacement.parent = parent;
// No children exist
} else replacement = null;
// Parent is null so significant empty space moves to the trailing nulls
if(parent == null) {
host.setRootNode(replacement);
if(whiteSpace != 0) host.addWhite(host.size() + 1, whiteSpace);
// This is a left child so empty space goes to the parent
} else if(parent.left == this) {
parent.whiteSpace += whiteSpace;
parent.treeLeftSize -= whiteSpace;
parent.left = replacement;
parent.ensureAVL();
if(rootSize != 0) parent.correctSizes(true, -rootSize, -rootSize, consistent);
clear();
// This is a right child so significant empty space must be reinserted
} else {
parent.right = replacement;
parent.ensureAVL();
if(whiteSpace != 0) {
parent.correctSizes(false, -rootSize, -(whiteSpace + rootSize), consistent);
host.addWhite(absoluteIndex, whiteSpace);
} else if(rootSize != 0) {
parent.correctSizes(false, -rootSize, -rootSize, consistent);
}
clear();
}
}
}
/**
* Unlinks this node in the special case where this node has both
* a left and right child.
*/
private void unlinkWithTwoChildren() {
// Get the replacement from the right subtree
BarcodeNode replacement = right.pruneSmallestChild();
BarcodeNode repParent = replacement.parent;
// Adjust sizes on this node
whiteSpace += replacement.whiteSpace;
rootSize = replacement.rootSize;
treeRightSize -= replacement.whiteSpace + replacement.rootSize;
blackRightSize -= replacement.rootSize;
// The smallest node is the right child of this
if(repParent == this) {
right = replacement.right;
if(right != null) right.parent = this;
ensureAVL();
// The smallest node is a left child in the right subtree
} else {
// linking on the right subtree needs updating
repParent.left = replacement.right;
if(repParent.left != null) repParent.left.parent = repParent;
repParent.ensureAVL();
}
replacement.clear();
}
/**
* Unlinks a node that has only a right child
*/
private void unlinkWithRightChild(boolean consistent) {
whiteSpace += right.whiteSpace;
int oldSize = rootSize;
rootSize = right.rootSize;
right.clear();
right = null;
blackRightSize = 0;
treeRightSize = 0;
height = 1;
if(parent != null) {
if(oldSize != 0) parent.correctSizes(parent.left == this, -oldSize, -oldSize, consistent);
parent.ensureAVL();
}
}
/**
* Prunes and returns the smallest child of the subtree rooted at this.
* Tree references are maintained out of necessity of the calling method,
* but sizes in the subtree are corrected accordingly.
*/
private BarcodeNode pruneSmallestChild() {
// Recurse to the left
if(left != null) {
BarcodeNode prunedNode = left.pruneSmallestChild();
blackLeftSize -= prunedNode.rootSize;
treeLeftSize -= prunedNode.whiteSpace + prunedNode.rootSize;
return prunedNode;
// return this node
} else return this;
}
/**
* A method to corrects sizes taking into account that the state of the
* cached tree sizes may be inconsistent from base-case set or remove.
*/
private void correctSizes(int blackOffset, int totalOffset, boolean consistent) {
if(consistent) correctSizes(blackOffset, totalOffset);
else correctSizes(-1, totalOffset - blackOffset);
}
/**
* A method to corrects sizes taking into account that the state of the
* cached tree sizes may be inconsistent from base-case set or remove.
*/
private void correctSizes(boolean leftChild, int blackOffset, int totalOffset, boolean consistent) {
if(consistent) correctSizes(leftChild, blackOffset, totalOffset);
else correctSizes(leftChild, -1, totalOffset - blackOffset);
}
/**
* Corrects all of the cached sizes up the tree by the given offsets starting
* at the parent if it exists.
*/
private void correctSizes(int blackOffset, int totalOffset) {
if(parent != null) parent.correctSizes(parent.left == this, blackOffset, totalOffset);
else host.treeSizeChanged();
}
/**
* Corrects all of the cached sizes up the tree by the given offsets starting
* from this.
*/
private void correctSizes(boolean leftChild, int blackOffset, int totalOffset) {
// left subtree is smaller
if(leftChild) {
blackLeftSize += blackOffset;
treeLeftSize += totalOffset;
// right subtree is smaller
} else {
blackRightSize += blackOffset;
treeRightSize += totalOffset;
}
// recurse up the tree to the root
if(parent != null) parent.correctSizes(parent.left == this, blackOffset, totalOffset);
// Notify the tree size has changed
else host.treeSizeChanged();
}
/**
* Clears this node and returns the value it had.
*/
private void clear() {
// clear the children
left = null;
blackLeftSize = 0;
treeLeftSize = 0;
right = null;
blackRightSize = 0;
treeRightSize = 0;
// clear this node
host = null;
parent = null;
whiteSpace = 0;
rootSize = 0;
height = -1;
}
/**
* Replaces a given child with the replacement node
*/
private void replace(BarcodeNode child, BarcodeNode replacement) {
// replacing the left child
if(child == left) left = replacement;
// Replacing the right child
else right = replacement;
}
/**
* Attempts to compress the current node out of the tree if possible
*/
private void compressNode(int absoluteIndex) {
// Fast fail if this node cannot be compressed
if(whiteSpace != 0) return;
// This is the root
if(parent == null) compressRoot(absoluteIndex);
// This is a left child
else if(parent.left == this) compressLeftChild(absoluteIndex);
// This is a right child
else compressRightChild(absoluteIndex);
}
/**
* Compresses the root node
*/
private void compressRoot(int absoluteIndex) {
// Compress to the left
if(left != null) {
// special case that's really fast
if(right == null) {
left.rootSize += rootSize;
left.parent = null;
host.setRootNode(left);
clear();
} else {
left.compressToTheRight(rootSize);
blackLeftSize += rootSize;
treeLeftSize += rootSize;
rootSize = 0;
unlink(absoluteIndex);
}
// The node is as compressed as possible
} else {
// Do Nothing
}
}
/**
* Compresses a node that is a left child
*/
private void compressLeftChild(int absoluteIndex) {
// Compress to the left
if(left != null) {
left.compressToTheRight(rootSize);
blackLeftSize += rootSize;
treeLeftSize += rootSize;
rootSize = 0;
unlink(absoluteIndex);
// Painful re-addition case
} else {
// This is the first value, can't compress it
if(absoluteIndex == 0) return;
// move the right child onto the parent
parent.left = right;
if(right != null) parent.left.parent = parent;
// fix tree state and re-add these values
parent.correctSizes(true, -rootSize, -rootSize);
parent.ensureAVL();
host.addBlack(absoluteIndex - 1, rootSize);
clear();
}
}
/**
* Compresses a node that is a right child
*/
private void compressRightChild(int absoluteIndex) {
// Compress to the parent
if(left == null) {
parent.blackRightSize -= rootSize;
parent.treeRightSize -= rootSize;
parent.rootSize += rootSize;
rootSize = 0;
unlink(absoluteIndex);
// Compress to the left
} else {
left.compressToTheRight(rootSize);
blackLeftSize += rootSize;
treeLeftSize += rootSize;
rootSize = 0;
unlink(absoluteIndex);
}
}
/**
* Compresses the given values into the largest node in this subtree.
*/
private void compressToTheRight(int values) {
if(right != null) {
blackRightSize += values;
treeRightSize += values;
right.compressToTheRight(values);
} else {
rootSize += values;
}
}
/**
* Ensures that the tree satisfies the AVL property. It is sufficient to
* recurse up the tree only as long as height recalculations are needed.
* As such, this method is intended to be called only on a node whose height
* may be out of sync due to an insertion or deletion. For example, calling
* this method on a leaf node will not guarantee that this tree satisfies the
* AVL property as it will not recurse.
*/
private void ensureAVL() {
int oldHeight = height;
recalculateHeight();
avlRotate();
// If adjustments were made, recurse up the tree
if(height != oldHeight && parent != null) parent.ensureAVL();
}
/**
* Recalculates the cached height at this level.
*/
private void recalculateHeight() {
int leftHeight = left == null ? 0 : left.height;
int rightHeight = right == null ? 0 : right.height;
height = 1 + Math.max(leftHeight, rightHeight);
}
/**
* Determines if AVL rotations are required and performs them if they are.
*/
private void avlRotate() {
// look up the left and right heights
int leftHeight = (left != null ? left.height : 0);
int rightHeight = (right != null ? right.height : 0);
// rotations will be on the left
if(leftHeight - rightHeight >= 2) {
// determine if a double rotation is necessary
int leftLeftHeight = (left.left != null ? left.left.height : 0);
int leftRightHeight = (left.right != null ? left.right.height : 0);
// Perform first half of double rotation if necessary
if(leftRightHeight > leftLeftHeight) left.rotateRight();
// Do the rotation for this node
rotateLeft();
// rotations will be on the right
} else if(rightHeight - leftHeight >= 2) {
// determine if a double rotation is necessary
int rightLeftHeight = (right.left != null ? right.left.height : 0);
int rightRightHeight = (right.right != null ? right.right.height : 0);
// Perform first half of double rotation if necessary
if(rightLeftHeight > rightRightHeight) right.rotateLeft();
// Do the rotation for this node
rotateRight();
}
}
/**
* AVL-Rotates this subtree with its left child.
*/
private void rotateLeft() {
// The replacement node is on the left
BarcodeNode replacement = left;
// take the right child of the replacement as my left child
left = replacement.right;
blackLeftSize = replacement.blackRightSize;
treeLeftSize = replacement.treeRightSize;
if(replacement.right != null) replacement.right.parent = this;
// set the right child of the replacement to this
replacement.right = this;
replacement.blackRightSize = blackSize();
replacement.treeRightSize = size();
// set the replacement's parent to my parent and mine to the replacement
if(parent != null) parent.replace(this, replacement);
// set a new tree root
else host.setRootNode(replacement);
// fix parent links on this and the replacement
replacement.parent = parent;
parent = replacement;
// recalculate height at this node
recalculateHeight();
// require height to be recalculated on the replacement node
replacement.height = 0;
}
/**
* AVL-Rotates this subtree with its right child.
*/
private void rotateRight() {
// The replacement node is on the right
BarcodeNode replacement = right;
// take the left child of the replacement as my right child
right = replacement.left;
blackRightSize = replacement.blackLeftSize;
treeRightSize = replacement.treeLeftSize;
if(replacement.left != null) replacement.left.parent = this;
// set the left child of the replacement to this
replacement.left = this;
replacement.blackLeftSize = blackSize();
replacement.treeLeftSize = size();
// set the replacement's parent to my parent and mine to the replacement
if(parent != null) parent.replace(this, replacement);
// set a new tree root
else host.setRootNode(replacement);
// fix parent links on this and the replacement
replacement.parent = parent;
parent = replacement;
// recalculate height at this node
recalculateHeight();
// require height to be recalculated on the replacement node
replacement.height = 0;
}
public String toString() {
return "[ " + left + " ("+ blackLeftSize +", " +treeLeftSize+")"
+" <"+whiteSpace+"> " + rootSize +" <"+height+"> "
+"(" + blackRightSize +", " +treeRightSize+") " + right + " ]";
}
/**
* Validates this node's state
*/
public void validate() {
validateLineage();
validateHeight();
validateTreeSize();
validateBlackSize();
validateCompression();
validateRootSize();
}
private int validateBlackSize() {
int leftTreeSize = left == null ? 0 : left.validateBlackSize();
int rightTreeSize = right == null ? 0 : right.validateBlackSize();
if(leftTreeSize != blackLeftSize) throw new IllegalStateException("Black Size Validation Failure in Left Subtree\n" + "Expected: " + leftTreeSize + "\nActual: " + blackLeftSize + "\n" + this);
if(rightTreeSize != blackRightSize) throw new IllegalStateException("Black Size Validation Failure in Right Subtree\n" + "Expected: " + rightTreeSize + "\nActual: " + blackRightSize + "\n" + this);
return leftTreeSize + rightTreeSize + rootSize;
}
private int validateHeight() {
int leftHeight = left == null ? 0 : left.validateHeight();
int rightHeight = right == null ? 0 : right.validateHeight();
// Validate that height is accurate at all
if(height != 1 + Math.max(leftHeight, rightHeight)) throw new IllegalStateException("Height Validation Failure\n" + "Expected: " + (1 + Math.max(leftHeight, rightHeight)) + "\nActual: " + height + "\n" + this);
// Validate that height meets the AVL property
if(Math.abs(leftHeight - rightHeight) > 1) throw new IllegalStateException("AVL Property Validation Failure\n" + this);
return 1 + Math.max(leftHeight, rightHeight);
}
private void validateLineage() {
if(left != null) {
if(left.parent != this) throw new IllegalStateException("Lineage Validation Failure\n" + "Left child is orphaned :\n" + left);
left.validateLineage();
}
if(right != null) {
if(right.parent != this) throw new IllegalStateException("Lineage Validation Failure\n" + "Right child is orphaned :\n" + right);
right.validateLineage();
}
}
private void validateCompression() {
if(left != null) left.validateCompression();
if(right != null) right.validateCompression();
if(whiteSpace == 0 && getIndexForValidation() != 0) throw new IllegalStateException("Compression Validation Failure\n" + "The following node was found that could be compressed: \n" + this);
}
private int validateTreeSize() {
int leftTreeSize = left == null ? 0 : left.validateTreeSize();
int rightTreeSize = right == null ? 0 : right.validateTreeSize();
if(treeLeftSize != leftTreeSize) throw new IllegalStateException("Tree Size Validation Failure\n" + "The following node was found that had a tree size failure on the left subtree: \n" + this);
if(treeRightSize != rightTreeSize) throw new IllegalStateException("Tree Size Validation Failure\n" + "The following node was found that had a tree size failure on the right subtree: \n" + this);
return treeLeftSize + whiteSpace + rootSize + treeRightSize;
}
/**
* Gets the index of the first element on this node. This is the index of
* the first WHITE element (or first BLACK if there is no whitespace on this node)
* indexed by this node.
*/
private int getIndexForValidation() {
if(parent != null) return parent.getIndexForValidation(this) + treeLeftSize;
return treeLeftSize;
}
private int getIndexForValidation(BarcodeNode child) {
// the child is on the left, return the index recursively
if(child == left) {
if(parent != null) return parent.getIndexForValidation(this);
return 0;
// the child is on the right, return the index recursively
} else {
if(parent != null) return parent.getIndexForValidation(this) + treeLeftSize + whiteSpace + rootSize;
return treeLeftSize + whiteSpace + rootSize;
}
}
private void validateRootSize() {
if(left != null) left.validateRootSize();
if(right != null) right.validateRootSize();
if(rootSize == 0) throw new IllegalStateException("Root Size Validation Failure\n" + "A node was found with a root size of zero.");
}
}