/* AbstractList.java -- Abstract implementation of most of List Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, Inc. This file is part of GNU Classpath. GNU Classpath is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. GNU Classpath is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GNU Classpath; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. Linking this library statically or dynamically with other modules is making a combined work based on this library. Thus, the terms and conditions of the GNU General Public License cover the whole combination. As a special exception, the copyright holders of this library give you permission to link this library with independent modules to produce an executable, regardless of the license terms of these independent modules, and to copy and distribute the resulting executable under terms of your choice, provided that you also meet, for each linked independent module, the terms and conditions of the license of that module. An independent module is a module which is not derived from or based on this library. If you modify this library, you may extend this exception to your version of the library, but you are not obligated to do so. If you do not wish to do so, delete this exception statement from your version. */ package java.util; /** * A basic implementation of most of the methods in the List interface to make * it easier to create a List based on a random-access data structure. If * the list is sequential (such as a linked list), use AbstractSequentialList. * To create an unmodifiable list, it is only necessary to override the * size() and get(int) methods (this contrasts with all other abstract * collection classes which require an iterator to be provided). To make the * list modifiable, the set(int, Object) method should also be overridden, and * to make the list resizable, the add(int, Object) and remove(int) methods * should be overridden too. Other methods should be overridden if the * backing data structure allows for a more efficient implementation. * The precise implementation used by AbstractList is documented, so that * subclasses can tell which methods could be implemented more efficiently. *
*
* As recommended by Collection and List, the subclass should provide at
* least a no-argument and a Collection constructor. This class is not
* synchronized.
*
* @author Original author unknown
* @author Bryce McKinlay
* @author Eric Blake
*
* To make lists fail-fast, increment this field by just 1 in the
*
*
* This implementation returns true if the object is this, or false if the
* object is not a List. Otherwise, it iterates over both lists (with
* iterator()), returning false if two elements compare false or one list
* is shorter, and true if the iteration completes successfully.
*
* @param o the object to test for equality with this list
* @return true if o is equal to this list
* @see Object#equals(Object)
* @see #hashCode()
*/
public boolean equals(Object o)
{
if (o == this)
return true;
if (! (o instanceof List))
return false;
int size = size();
if (size != ((List) o).size())
return false;
Iterator itr1 = iterator();
Iterator itr2 = ((List) o).iterator();
while (--size >= 0)
if (! equals(itr1.next(), itr2.next()))
return false;
return true;
}
/**
* Obtains a hash code for this list. In order to obey the general
* contract of the hashCode method of class Object, this value is
* calculated as follows:
*
*
* This implementation uses size(), get(int), set(int, Object),
* add(int, Object), and remove(int) of the backing list, and does not
* support remove, set, or add unless the list does. This implementation
* is fail-fast if you correctly maintain modCount.
*
* @param index the position, between 0 and size() inclusive, to begin the
* iteration from
* @return a ListIterator over the elements of this list, in order, starting
* at index
* @throws IndexOutOfBoundsException if index < 0 || index > size()
* @see #modCount
*/
public ListIterator listIterator(final int index)
{
if (index < 0 || index > size())
throw new IndexOutOfBoundsException("Index: " + index + ", Size:"
+ size());
return new ListIterator()
{
private int knownMod = modCount;
private int position = index;
private int lastReturned = -1;
private int size = size();
// This will get inlined, since it is private.
private void checkMod()
{
if (knownMod != modCount)
throw new ConcurrentModificationException();
}
public boolean hasNext()
{
checkMod();
return position < size;
}
public boolean hasPrevious()
{
checkMod();
return position > 0;
}
public Object next()
{
checkMod();
if (position == size)
throw new NoSuchElementException();
lastReturned = position;
return get(position++);
}
public Object previous()
{
checkMod();
if (position == 0)
throw new NoSuchElementException();
lastReturned = --position;
return get(lastReturned);
}
public int nextIndex()
{
checkMod();
return position;
}
public int previousIndex()
{
checkMod();
return position - 1;
}
public void remove()
{
checkMod();
if (lastReturned < 0)
throw new IllegalStateException();
AbstractList.this.remove(lastReturned);
size--;
position = lastReturned;
lastReturned = -1;
knownMod = modCount;
}
public void set(Object o)
{
checkMod();
if (lastReturned < 0)
throw new IllegalStateException();
AbstractList.this.set(lastReturned, o);
}
public void add(Object o)
{
checkMod();
AbstractList.this.add(position++, o);
size++;
lastReturned = -1;
knownMod = modCount;
}
};
}
/**
* Remove the element at a given position in this list (optional operation).
* Shifts all remaining elements to the left to fill the gap. This
* implementation always throws an UnsupportedOperationException.
* If you want fail-fast iterators, be sure to increment modCount when
* overriding this.
*
* @param index the position within the list of the object to remove
* @return the object that was removed
* @throws UnsupportedOperationException if this list does not support the
* remove operation
* @throws IndexOutOfBoundsException if index < 0 || index >= size()
* @see #modCount
*/
public Object remove(int index)
{
throw new UnsupportedOperationException();
}
/**
* Remove a subsection of the list. This is called by the clear and
* removeRange methods of the class which implements subList, which are
* difficult for subclasses to override directly. Therefore, this method
* should be overridden instead by the more efficient implementation, if one
* exists. Overriding this can reduce quadratic efforts to constant time
* in some cases!
*
*
* This implementation first checks for illegal or out of range arguments. It
* then obtains a ListIterator over the list using listIterator(fromIndex).
* It then calls next() and remove() on this iterator repeatedly, toIndex -
* fromIndex times.
*
* @param fromIndex the index, inclusive, to remove from.
* @param toIndex the index, exclusive, to remove to.
*/
protected void removeRange(int fromIndex, int toIndex)
{
ListIterator itr = listIterator(fromIndex);
for (int index = fromIndex; index < toIndex; index++)
{
itr.next();
itr.remove();
}
}
/**
* Replace an element of this list with another object (optional operation).
* This implementation always throws an UnsupportedOperationException.
*
* @param index the position within this list of the element to be replaced
* @param o the object to replace it with
* @return the object that was replaced
* @throws UnsupportedOperationException if this list does not support the
* set operation
* @throws IndexOutOfBoundsException if index < 0 || index >= size()
* @throws ClassCastException if o cannot be added to this list due to its
* type
* @throws IllegalArgumentException if o cannot be added to this list for
* some other reason
*/
public Object set(int index, Object o)
{
throw new UnsupportedOperationException();
}
/**
* Obtain a List view of a subsection of this list, from fromIndex
* (inclusive) to toIndex (exclusive). If the two indices are equal, the
* sublist is empty. The returned list should be modifiable if and only
* if this list is modifiable. Changes to the returned list should be
* reflected in this list. If this list is structurally modified in
* any way other than through the returned list, the result of any subsequent
* operations on the returned list is undefined.
*
*
* This implementation returns a subclass of AbstractList. It stores, in
* private fields, the offset and size of the sublist, and the expected
* modCount of the backing list. If the backing list implements RandomAccess,
* the sublist will also.
*
*
* The subclass's
*
* All methods first check to see if the actual modCount of the backing
* list is equal to its expected value, and throw a
* ConcurrentModificationException if it is not.
*
* @param fromIndex the index that the returned list should start from
* (inclusive)
* @param toIndex the index that the returned list should go to (exclusive)
* @return a List backed by a subsection of this list
* @throws IndexOutOfBoundsException if fromIndex < 0
* || toIndex > size()
* @throws IllegalArgumentException if fromIndex > toIndex
* @see ConcurrentModificationException
* @see RandomAccess
*/
public List subList(int fromIndex, int toIndex)
{
// This follows the specification of AbstractList, but is inconsistent
// with the one in List. Don't you love Sun's inconsistencies?
if (fromIndex > toIndex)
throw new IllegalArgumentException(fromIndex + " > " + toIndex);
if (fromIndex < 0 || toIndex > size())
throw new IndexOutOfBoundsException();
if (this instanceof RandomAccess)
return new RandomAccessSubList(this, fromIndex, toIndex);
return new SubList(this, fromIndex, toIndex);
}
} // class AbstractList
/**
* This class follows the implementation requirements set forth in
* {@link AbstractList#subList(int, int)}. It matches Sun's implementation
* by using a non-public top-level class in the same package.
*
* @author Original author unknown
* @author Eric Blake add(int, Object)
and remove(int)
methods.
* Otherwise, this field may be ignored.
*/
protected int modCount;
/**
* The main constructor, for use by subclasses.
*/
protected AbstractList()
{
}
/**
* Returns the elements at the specified position in the list.
*
* @param index the element to return
* @return the element at that position
* @throws IndexOutOfBoundsException if index < 0 || index >= size()
*/
public abstract Object get(int index);
/**
* Insert an element into the list at a given position (optional operation).
* This shifts all existing elements from that position to the end one
* index to the right. This version of add has no return, since it is
* assumed to always succeed if there is no exception. This implementation
* always throws UnsupportedOperationException, and must be overridden to
* make a modifiable List. If you want fail-fast iterators, be sure to
* increment modCount when overriding this.
*
* @param index the location to insert the item
* @param o the object to insert
* @throws UnsupportedOperationException if this list does not support the
* add operation
* @throws IndexOutOfBoundsException if index < 0 || index > size()
* @throws ClassCastException if o cannot be added to this list due to its
* type
* @throws IllegalArgumentException if o cannot be added to this list for
* some other reason
* @see #modCount
*/
public void add(int index, Object o)
{
throw new UnsupportedOperationException();
}
/**
* Add an element to the end of the list (optional operation). If the list
* imposes restraints on what can be inserted, such as no null elements,
* this should be documented. This implementation calls
* add(size(), o);
, and will fail if that version does.
*
* @param o the object to add
* @return true, as defined by Collection for a modified list
* @throws UnsupportedOperationException if this list does not support the
* add operation
* @throws ClassCastException if o cannot be added to this list due to its
* type
* @throws IllegalArgumentException if o cannot be added to this list for
* some other reason
* @see #add(int, Object)
*/
public boolean add(Object o)
{
add(size(), o);
return true;
}
/**
* Insert the contents of a collection into the list at a given position
* (optional operation). Shift all elements at that position to the right
* by the number of elements inserted. This operation is undefined if
* this list is modified during the operation (for example, if you try
* to insert a list into itself). This implementation uses the iterator of
* the collection, repeatedly calling add(int, Object); this will fail
* if add does. This can often be made more efficient.
*
* @param index the location to insert the collection
* @param c the collection to insert
* @return true if the list was modified by this action, that is, if c is
* non-empty
* @throws UnsupportedOperationException if this list does not support the
* addAll operation
* @throws IndexOutOfBoundsException if index < 0 || index > size()
* @throws ClassCastException if some element of c cannot be added to this
* list due to its type
* @throws IllegalArgumentException if some element of c cannot be added
* to this list for some other reason
* @throws NullPointerException if the specified collection is null
* @see #add(int, Object)
*/
public boolean addAll(int index, Collection c)
{
Iterator itr = c.iterator();
int size = c.size();
for (int pos = size; pos > 0; pos--)
add(index++, itr.next());
return size > 0;
}
/**
* Clear the list, such that a subsequent call to isEmpty() would return
* true (optional operation). This implementation calls
* removeRange(0, size())
, so it will fail unless remove
* or removeRange is overridden.
*
* @throws UnsupportedOperationException if this list does not support the
* clear operation
* @see #remove(int)
* @see #removeRange(int, int)
*/
public void clear()
{
removeRange(0, size());
}
/**
* Test whether this list is equal to another object. A List is defined to be
* equal to an object if and only if that object is also a List, and the two
* lists have the same sequence. Two lists l1 and l2 are equal if and only
* if l1.size() == l2.size()
, and for every integer n between 0
* and l1.size() - 1
inclusive, l1.get(n) == null ?
* l2.get(n) == null : l1.get(n).equals(l2.get(n))
.
* hashCode = 1;
Iterator i = list.iterator();
while (i.hasNext())
{
Object obj = i.next();
hashCode = 31 * hashCode + (obj == null ? 0 : obj.hashCode());
}
*
* This ensures that the general contract of Object.hashCode() is adhered to.
*
* @return the hash code of this list
*
* @see Object#hashCode()
* @see #equals(Object)
*/
public int hashCode()
{
int hashCode = 1;
Iterator itr = iterator();
int pos = size();
while (--pos >= 0)
hashCode = 31 * hashCode + hashCode(itr.next());
return hashCode;
}
/**
* Obtain the first index at which a given object is to be found in this
* list. This implementation follows a listIterator() until a match is found,
* or returns -1 if the list end is reached.
*
* @param o the object to search for
* @return the least integer n such that o == null ? get(n) == null :
* o.equals(get(n))
, or -1 if there is no such index
*/
public int indexOf(Object o)
{
ListIterator itr = listIterator();
int size = size();
for (int pos = 0; pos < size; pos++)
if (equals(o, itr.next()))
return pos;
return -1;
}
/**
* Obtain an Iterator over this list, whose sequence is the list order.
* This implementation uses size(), get(int), and remove(int) of the
* backing list, and does not support remove unless the list does. This
* implementation is fail-fast if you correctly maintain modCount.
* Also, this implementation is specified by Sun to be distinct from
* listIterator, although you could easily implement it as
* return listIterator(0)
.
*
* @return an Iterator over the elements of this list, in order
* @see #modCount
*/
public Iterator iterator()
{
// Bah, Sun's implementation forbids using listIterator(0).
return new Iterator()
{
private int pos = 0;
private int size = size();
private int last = -1;
private int knownMod = modCount;
// This will get inlined, since it is private.
private void checkMod()
{
if (knownMod != modCount)
throw new ConcurrentModificationException();
}
public boolean hasNext()
{
checkMod();
return pos < size;
}
public Object next()
{
checkMod();
if (pos == size)
throw new NoSuchElementException();
last = pos;
return get(pos++);
}
public void remove()
{
checkMod();
if (last < 0)
throw new IllegalStateException();
AbstractList.this.remove(last);
pos--;
size--;
last = -1;
knownMod = modCount;
}
};
}
/**
* Obtain the last index at which a given object is to be found in this
* list. This implementation grabs listIterator(size()), then searches
* backwards for a match or returns -1.
*
* @return the greatest integer n such that o == null ? get(n) == null
* : o.equals(get(n))
, or -1 if there is no such index
*/
public int lastIndexOf(Object o)
{
int pos = size();
ListIterator itr = listIterator(pos);
while (--pos >= 0)
if (equals(o, itr.previous()))
return pos;
return -1;
}
/**
* Obtain a ListIterator over this list, starting at the beginning. This
* implementation returns listIterator(0).
*
* @return a ListIterator over the elements of this list, in order, starting
* at the beginning
*/
public ListIterator listIterator()
{
return listIterator(0);
}
/**
* Obtain a ListIterator over this list, starting at a given position.
* A first call to next() would return the same as get(index), and a
* first call to previous() would return the same as get(index - 1).
* set(int, Object)
, get(int)
,
* add(int, Object)
, remove(int)
,
* addAll(int, Collection)
and
* removeRange(int, int)
methods all delegate to the
* corresponding methods on the backing abstract list, after
* bounds-checking the index and adjusting for the offset. The
* addAll(Collection c)
method merely returns addAll(size, c).
* The listIterator(int)
method returns a "wrapper object"
* over a list iterator on the backing list, which is created with the
* corresponding method on the backing list. The iterator()
* method merely returns listIterator(), and the size()
method
* merely returns the subclass's size field.
*