bundleplugin/src/main/java/aQute/bnd/differ/DiffImpl.java - onos-felix - Gitiles

 package aQute.bnd.differ;

 import static aQute.bnd.service.diff.Delta.*;

 import java.util.*;

 import aQute.bnd.service.diff.*;

 /**
  * A DiffImpl class compares a newer Element to an older Element. The Element
  * classes hide all the low level details. A Element class is either either
  * Structured (has children) or it is a Leaf, it only has a value. The
  * constructor will first build its children (if any) and then calculate the
  * delta. Each comparable element is translated to an Element. If necessary the
  * Element can be sub classed to provide special behavior.
  */

 public class DiffImpl implements Diff, Comparable<DiffImpl> {

 	final Tree				older;
 	final Tree				newer;
 	final Collection<DiffImpl>	children;
 	final Delta					delta;

 	/**
 	 * The transitions table defines how the state is escalated depending on the
 	 * children. horizontally is the current delta and this is indexed with the
 	 * child delta for each child. This escalates deltas from below up.
 	 */
 	final static Delta[][]		TRANSITIONS	= {
 			{
 			IGNORED, UNCHANGED, CHANGED, MICRO, MINOR, MAJOR
 			}, // IGNORED
 			{
 			IGNORED, UNCHANGED, CHANGED, MICRO, MINOR, MAJOR
 			}, // UNCHANGED
 			{
 			IGNORED, CHANGED, CHANGED, MICRO, MINOR, MAJOR
 			}, // CHANGED
 			{
 			IGNORED, MICRO, MICRO, MICRO, MINOR, MAJOR
 			}, // MICRO
 			{
 			IGNORED, MINOR, MINOR, MINOR, MINOR, MAJOR
 			}, // MINOR
 			{
 			IGNORED, MAJOR, MAJOR, MAJOR, MAJOR, MAJOR
 			}, // MAJOR
 			{
 			IGNORED, MAJOR, MAJOR, MAJOR, MAJOR, MAJOR
 			}, // REMOVED
 			{
 			IGNORED, MINOR, MINOR, MINOR, MINOR, MAJOR
 			}, // ADDED
 											};

 	/**
 	 * Compares the newer against the older, traversing the children if
 	 * necessary.
 	 *
 	 * @param newer
 	 *            The newer Element
 	 * @param older
 	 *            The older Element
 	 * @param types
 	 */
 	public DiffImpl(Tree newer, Tree older) {
 		assert newer != null || older != null;
 		this.older = older;
 		this.newer = newer;

 		// Either newer or older can be null, indicating remove or add
 		// so we have to be very careful.
 		Tree[] newerChildren = newer == null ? Element.EMPTY : newer.getChildren();
 		Tree[] olderChildren = older == null ? Element.EMPTY : older.getChildren();

 		int o = 0;
 		int n = 0;
 		List<DiffImpl> children = new ArrayList<DiffImpl>();
 		while (true) {
 			Tree nw = n < newerChildren.length ? newerChildren[n] : null;
 			Tree ol = o < olderChildren.length ? olderChildren[o] : null;
 			DiffImpl diff;

 			if (nw == null && ol == null)
 				break;

 			if (nw != null && ol != null) {
 				// we have both sides
 				int result = nw.compareTo(ol);
 				if (result == 0) {
 					// we have two equal named elements
 					// use normal diff
 					diff = new DiffImpl(nw, ol);
 					n++;
 					o++;
 				} else if (result > 0) {
 					// we newer > older, so there is no newer == removed
 					diff = new DiffImpl(null, ol);
 					o++;
 				} else {
 					// we newer < older, so there is no older == added
 					diff = new DiffImpl(nw, null);
 					n++;
 				}
 			} else {
 				// we reached the end of one of the list
 				diff = new DiffImpl(nw, ol);
 				n++;
 				o++;
 			}
 			children.add(diff);
 		}

 		// make sure they're read only
 		this.children = Collections.unmodifiableCollection(children);
 		delta = getDelta(null);
 	}

 	/**
 	 * Return the absolute delta. Also see
 	 * {@link #getDelta(aQute.bnd.service.diff.Diff.Ignore)} that allows you to
 	 * ignore Diff objects on the fly (and calculate their parents accordingly).
 	 */
 	public Delta getDelta() {
 		return delta;
 	}

 	/**
 	 * This getDelta calculates the delta but allows the caller to ignore
 	 * certain Diff objects by calling back the ignore call back parameter. This
 	 * can be useful to ignore warnings/errors.
 	 */

 	public Delta getDelta(Ignore ignore) {

 		// If ignored, we just return ignore.
 		if (ignore != null && ignore.contains(this))
 			return IGNORED;

 		if (newer == null) {
 			return REMOVED;
 		} else if (older == null) {
 			return ADDED;
 		} else {
 			// now we're sure newer and older are both not null
 			assert newer != null && older != null;
 			assert newer.getClass() == older.getClass();

 			Delta local = Delta.UNCHANGED;

 			for (DiffImpl child : children) {
 				Delta sub = child.getDelta(ignore);
 				if (sub == REMOVED)
 					sub = child.older.ifRemoved();
 				else if (sub == ADDED)
 					sub = child.newer.ifAdded();

 				// The escalate method is used to calculate the default
 				// transition in the
 				// delta based on the children. In general the delta can
 				// only escalate, i.e.
 				// move up in the chain.

 				local = TRANSITIONS[sub.ordinal()][local.ordinal()];
 			}
 			return local;
 		}
 	}

 	public Type getType() {
 		return (newer == null ? older : newer).getType();
 	}

 	public String getName() {
 		return (newer == null ? older : newer).getName();
 	}

 	public Collection< ? extends Diff> getChildren() {
 		return children;
 	}

 	public String toString() {
 		return String.format("%-10s %-10s %s", getDelta(), getType(), getName());
 	}

 	public boolean equals(Object other) {
 		if (other instanceof DiffImpl) {
 			DiffImpl o = (DiffImpl) other;
 			return getDelta() == o.getDelta() && getType() == o.getType() && getName().equals(o.getName());
 		}
 		return false;
 	}

 	public int hashCode() {
 		return getDelta().hashCode() ^ getType().hashCode() ^ getName().hashCode();
 	}

 	public int compareTo(DiffImpl other) {
 		if (getDelta() == other.getDelta()) {
 			if (getType() == other.getType()) {
 				return getName().compareTo(other.getName());
 			} else
 				return getType().compareTo(other.getType());
 		} else
 			return getDelta().compareTo(other.getDelta());
 	}

 	public Diff get(String name) {
 		for (DiffImpl child : children) {
 			if (child.getName().equals(name))
 				return child;
 		}
 		return null;
 	}

 	public Tree getOlder() {
 		return older;
 	}

 	public Tree getNewer() {
 		return newer;
 	}

 	public Data serialize() {
 		Data data = new Data();
 		data.type = getType();
 		data.delta = delta;
 		data.name = getName();
 		data.children = new Data[children.size()];

 		int i=0;
 		for ( Diff d : children)
 			data.children[i++] = d.serialize();

 		return data;
 	}


 }
	package aQute.bnd.differ;

	import static aQute.bnd.service.diff.Delta.*;

	import java.util.*;

	import aQute.bnd.service.diff.*;

	/**
	* A DiffImpl class compares a newer Element to an older Element. The Element
	* classes hide all the low level details. A Element class is either either
	* Structured (has children) or it is a Leaf, it only has a value. The
	* constructor will first build its children (if any) and then calculate the
	* delta. Each comparable element is translated to an Element. If necessary the
	* Element can be sub classed to provide special behavior.
	*/

	public class DiffImpl implements Diff, Comparable<DiffImpl> {

	final Tree older;
	final Tree newer;
	final Collection<DiffImpl> children;
	final Delta delta;

	/**
	* The transitions table defines how the state is escalated depending on the
	* children. horizontally is the current delta and this is indexed with the
	* child delta for each child. This escalates deltas from below up.
	*/
	final static Delta[][] TRANSITIONS = {
	{
	IGNORED, UNCHANGED, CHANGED, MICRO, MINOR, MAJOR
	}, // IGNORED
	{
	IGNORED, UNCHANGED, CHANGED, MICRO, MINOR, MAJOR
	}, // UNCHANGED
	{
	IGNORED, CHANGED, CHANGED, MICRO, MINOR, MAJOR
	}, // CHANGED
	{
	IGNORED, MICRO, MICRO, MICRO, MINOR, MAJOR
	}, // MICRO
	{
	IGNORED, MINOR, MINOR, MINOR, MINOR, MAJOR
	}, // MINOR
	{
	IGNORED, MAJOR, MAJOR, MAJOR, MAJOR, MAJOR
	}, // MAJOR
	{
	IGNORED, MAJOR, MAJOR, MAJOR, MAJOR, MAJOR
	}, // REMOVED
	{
	IGNORED, MINOR, MINOR, MINOR, MINOR, MAJOR
	}, // ADDED
	};

	/**
	* Compares the newer against the older, traversing the children if
	* necessary.
	*
	* @param newer
	* The newer Element
	* @param older
	* The older Element
	* @param types
	*/
	public DiffImpl(Tree newer, Tree older) {
	assert newer != null \|\| older != null;
	this.older = older;
	this.newer = newer;

	// Either newer or older can be null, indicating remove or add
	// so we have to be very careful.
	Tree[] newerChildren = newer == null ? Element.EMPTY : newer.getChildren();
	Tree[] olderChildren = older == null ? Element.EMPTY : older.getChildren();

	int o = 0;
	int n = 0;
	List<DiffImpl> children = new ArrayList<DiffImpl>();
	while (true) {
	Tree nw = n < newerChildren.length ? newerChildren[n] : null;
	Tree ol = o < olderChildren.length ? olderChildren[o] : null;
	DiffImpl diff;

	if (nw == null && ol == null)
	break;

	if (nw != null && ol != null) {
	// we have both sides
	int result = nw.compareTo(ol);
	if (result == 0) {
	// we have two equal named elements
	// use normal diff
	diff = new DiffImpl(nw, ol);
	n++;
	o++;
	} else if (result > 0) {
	// we newer > older, so there is no newer == removed
	diff = new DiffImpl(null, ol);
	o++;
	} else {
	// we newer < older, so there is no older == added
	diff = new DiffImpl(nw, null);
	n++;
	}
	} else {
	// we reached the end of one of the list
	diff = new DiffImpl(nw, ol);
	n++;
	o++;
	}
	children.add(diff);
	}

	// make sure they're read only
	this.children = Collections.unmodifiableCollection(children);
	delta = getDelta(null);
	}

	/**
	* Return the absolute delta. Also see
	* {@link #getDelta(aQute.bnd.service.diff.Diff.Ignore)} that allows you to
	* ignore Diff objects on the fly (and calculate their parents accordingly).
	*/
	public Delta getDelta() {
	return delta;
	}

	/**
	* This getDelta calculates the delta but allows the caller to ignore
	* certain Diff objects by calling back the ignore call back parameter. This
	* can be useful to ignore warnings/errors.
	*/

	public Delta getDelta(Ignore ignore) {

	// If ignored, we just return ignore.
	if (ignore != null && ignore.contains(this))
	return IGNORED;

	if (newer == null) {
	return REMOVED;
	} else if (older == null) {
	return ADDED;
	} else {
	// now we're sure newer and older are both not null
	assert newer != null && older != null;
	assert newer.getClass() == older.getClass();

	Delta local = Delta.UNCHANGED;

	for (DiffImpl child : children) {
	Delta sub = child.getDelta(ignore);
	if (sub == REMOVED)
	sub = child.older.ifRemoved();
	else if (sub == ADDED)
	sub = child.newer.ifAdded();

	// The escalate method is used to calculate the default
	// transition in the
	// delta based on the children. In general the delta can
	// only escalate, i.e.
	// move up in the chain.

	local = TRANSITIONS[sub.ordinal()][local.ordinal()];
	}
	return local;
	}
	}

	public Type getType() {
	return (newer == null ? older : newer).getType();
	}

	public String getName() {
	return (newer == null ? older : newer).getName();
	}

	public Collection< ? extends Diff> getChildren() {
	return children;
	}

	public String toString() {
	return String.format("%-10s %-10s %s", getDelta(), getType(), getName());
	}

	public boolean equals(Object other) {
	if (other instanceof DiffImpl) {
	DiffImpl o = (DiffImpl) other;
	return getDelta() == o.getDelta() && getType() == o.getType() && getName().equals(o.getName());
	}
	return false;
	}

	public int hashCode() {
	return getDelta().hashCode() ^ getType().hashCode() ^ getName().hashCode();
	}

	public int compareTo(DiffImpl other) {
	if (getDelta() == other.getDelta()) {
	if (getType() == other.getType()) {
	return getName().compareTo(other.getName());
	} else
	return getType().compareTo(other.getType());
	} else
	return getDelta().compareTo(other.getDelta());
	}

	public Diff get(String name) {
	for (DiffImpl child : children) {
	if (child.getName().equals(name))
	return child;
	}
	return null;
	}

	public Tree getOlder() {
	return older;
	}

	public Tree getNewer() {
	return newer;
	}

	public Data serialize() {
	Data data = new Data();
	data.type = getType();
	data.delta = delta;
	data.name = getName();
	data.children = new Data[children.size()];

	int i=0;
	for ( Diff d : children)
	data.children[i++] = d.serialize();

	return data;
	}


	}