tools/splaytree.py - platform/external/v8 - Git at Google

 # Copyright 2008 the V8 project authors. All rights reserved.
 # Redistribution and use in source and binary forms, with or without
 # modification, are permitted provided that the following conditions are
 # met:
 #
 #     * Redistributions of source code must retain the above copyright
 #       notice, this list of conditions and the following disclaimer.
 #     * Redistributions in binary form must reproduce the above
 #       copyright notice, this list of conditions and the following
 #       disclaimer in the documentation and/or other materials provided
 #       with the distribution.
 #     * Neither the name of Google Inc. nor the names of its
 #       contributors may be used to endorse or promote products derived
 #       from this software without specific prior written permission.
 #
 # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


 class Node(object):
   """Nodes in the splay tree."""

   def __init__(self, key, value):
     self.key = key
     self.value = value
     self.left = None
     self.right = None


 class KeyNotFoundError(Exception):
   """KeyNotFoundError is raised when removing a non-existing node."""

   def __init__(self, key):
     self.key = key


 class SplayTree(object):
   """The splay tree itself is just a reference to the root of the tree."""

   def __init__(self):
     """Create a new SplayTree."""
     self.root = None

   def IsEmpty(self):
     """Is the SplayTree empty?"""
     return not self.root

   def Insert(self, key, value):
     """Insert a new node in the SplayTree."""
     # If the tree is empty, insert the new node.
     if self.IsEmpty():
       self.root = Node(key, value)
       return
     # Splay on the key to move the last node on the search path for
     # the key to the root of the tree.
     self.Splay(key)
     # Ignore repeated insertions with the same key.
     if self.root.key == key:
       return
     # Insert the new node.
     node = Node(key, value)
     if key > self.root.key:
       node.left = self.root
       node.right = self.root.right
       self.root.right = None
     else:
       node.right = self.root
       node.left = self.root.left
       self.root.left = None
     self.root = node

   def Remove(self, key):
     """Remove the node with the given key from the SplayTree."""
     # Raise exception for key that is not found if the tree is empty.
     if self.IsEmpty():
       raise KeyNotFoundError(key)
     # Splay on the key to move the node with the given key to the top.
     self.Splay(key)
     # Raise exception for key that is not found.
     if self.root.key != key:
       raise KeyNotFoundError(key)
     removed = self.root
     # Link out the root node.
     if not self.root.left:
       # No left child, so the new tree is just the right child.
       self.root = self.root.right
     else:
       # Left child exists.
       right = self.root.right
       # Make the original left child the new root.
       self.root = self.root.left
       # Splay to make sure that the new root has an empty right child.
       self.Splay(key)
       # Insert the original right child as the right child of the new
       # root.
       self.root.right = right
     return removed

   def Find(self, key):
     """Returns the node with the given key or None if no such node exists."""
     if self.IsEmpty():
       return None
     self.Splay(key)
     if self.root.key == key:
       return self.root
     return None

   def FindMax(self):
     """Returns the node with the largest key value."""
     if self.IsEmpty():
       return None
     current = self.root
     while current.right != None:
       current = current.right
     return current

   # Returns the node with the smallest key value.
   def FindMin(self):
     if self.IsEmpty():
       return None
     current = self.root
     while current.left != None:
       current = current.left
     return current

   def FindGreatestsLessThan(self, key):
     """Returns node with greatest key less than or equal to the given key."""
     if self.IsEmpty():
       return None
     # Splay on the key to move the node with the given key or the last
     # node on the search path to the top of the tree.
     self.Splay(key)
     # Now the result is either the root node or the greatest node in
     # the left subtree.
     if self.root.key <= key:
       return self.root
     else:
       tmp = self.root
       self.root = self.root.left
       result = self.FindMax()
       self.root = tmp
       return result

   def ExportValueList(self):
     """Returns a list containing all the values of the nodes in the tree."""
     result = []
     nodes_to_visit = [self.root]
     while len(nodes_to_visit) > 0:
       node = nodes_to_visit.pop()
       if not node:
         continue
       result.append(node.value)
       nodes_to_visit.append(node.left)
       nodes_to_visit.append(node.right)
     return result

   def Splay(self, key):
     """Perform splay operation.

     Perform the splay operation for the given key. Moves the node with
     the given key to the top of the tree.  If no node has the given
     key, the last node on the search path is moved to the top of the
     tree.

     This uses the simplified top-down splaying algorithm from:

     "Self-adjusting Binary Search Trees" by Sleator and Tarjan

     """
     if self.IsEmpty():
       return
     # Create a dummy node.  The use of the dummy node is a bit
     # counter-intuitive: The right child of the dummy node will hold
     # the L tree of the algorithm.  The left child of the dummy node
     # will hold the R tree of the algorithm.  Using a dummy node, left
     # and right will always be nodes and we avoid special cases.
     dummy = left = right = Node(None, None)
     current = self.root
     while True:
       if key < current.key:
         if not current.left:
           break
         if key < current.left.key:
           # Rotate right.
           tmp = current.left
           current.left = tmp.right
           tmp.right = current
           current = tmp
           if not current.left:
             break
         # Link right.
         right.left = current
         right = current
         current = current.left
       elif key > current.key:
         if not current.right:
           break
         if key > current.right.key:
           # Rotate left.
           tmp = current.right
           current.right = tmp.left
           tmp.left = current
           current = tmp
           if not current.right:
             break
         # Link left.
         left.right = current
         left = current
         current = current.right
       else:
         break
     # Assemble.
     left.right = current.left
     right.left = current.right
     current.left = dummy.right
     current.right = dummy.left
     self.root = current
	# Copyright 2008 the V8 project authors. All rights reserved.
	# Redistribution and use in source and binary forms, with or without
	# modification, are permitted provided that the following conditions are
	# met:
	#
	# * Redistributions of source code must retain the above copyright
	# notice, this list of conditions and the following disclaimer.
	# * Redistributions in binary form must reproduce the above
	# copyright notice, this list of conditions and the following
	# disclaimer in the documentation and/or other materials provided
	# with the distribution.
	# * Neither the name of Google Inc. nor the names of its
	# contributors may be used to endorse or promote products derived
	# from this software without specific prior written permission.
	#
	# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	# OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


	class Node(object):
	"""Nodes in the splay tree."""

	def __init__(self, key, value):
	self.key = key
	self.value = value
	self.left = None
	self.right = None


	class KeyNotFoundError(Exception):
	"""KeyNotFoundError is raised when removing a non-existing node."""

	def __init__(self, key):
	self.key = key


	class SplayTree(object):
	"""The splay tree itself is just a reference to the root of the tree."""

	def __init__(self):
	"""Create a new SplayTree."""
	self.root = None

	def IsEmpty(self):
	"""Is the SplayTree empty?"""
	return not self.root

	def Insert(self, key, value):
	"""Insert a new node in the SplayTree."""
	# If the tree is empty, insert the new node.
	if self.IsEmpty():
	self.root = Node(key, value)
	return
	# Splay on the key to move the last node on the search path for
	# the key to the root of the tree.
	self.Splay(key)
	# Ignore repeated insertions with the same key.
	if self.root.key == key:
	return
	# Insert the new node.
	node = Node(key, value)
	if key > self.root.key:
	node.left = self.root
	node.right = self.root.right
	self.root.right = None
	else:
	node.right = self.root
	node.left = self.root.left
	self.root.left = None
	self.root = node

	def Remove(self, key):
	"""Remove the node with the given key from the SplayTree."""
	# Raise exception for key that is not found if the tree is empty.
	if self.IsEmpty():
	raise KeyNotFoundError(key)
	# Splay on the key to move the node with the given key to the top.
	self.Splay(key)
	# Raise exception for key that is not found.
	if self.root.key != key:
	raise KeyNotFoundError(key)
	removed = self.root
	# Link out the root node.
	if not self.root.left:
	# No left child, so the new tree is just the right child.
	self.root = self.root.right
	else:
	# Left child exists.
	right = self.root.right
	# Make the original left child the new root.
	self.root = self.root.left
	# Splay to make sure that the new root has an empty right child.
	self.Splay(key)
	# Insert the original right child as the right child of the new
	# root.
	self.root.right = right
	return removed

	def Find(self, key):
	"""Returns the node with the given key or None if no such node exists."""
	if self.IsEmpty():
	return None
	self.Splay(key)
	if self.root.key == key:
	return self.root
	return None

	def FindMax(self):
	"""Returns the node with the largest key value."""
	if self.IsEmpty():
	return None
	current = self.root
	while current.right != None:
	current = current.right
	return current

	# Returns the node with the smallest key value.
	def FindMin(self):
	if self.IsEmpty():
	return None
	current = self.root
	while current.left != None:
	current = current.left
	return current

	def FindGreatestsLessThan(self, key):
	"""Returns node with greatest key less than or equal to the given key."""
	if self.IsEmpty():
	return None
	# Splay on the key to move the node with the given key or the last
	# node on the search path to the top of the tree.
	self.Splay(key)
	# Now the result is either the root node or the greatest node in
	# the left subtree.
	if self.root.key <= key:
	return self.root
	else:
	tmp = self.root
	self.root = self.root.left
	result = self.FindMax()
	self.root = tmp
	return result

	def ExportValueList(self):
	"""Returns a list containing all the values of the nodes in the tree."""
	result = []
	nodes_to_visit = [self.root]
	while len(nodes_to_visit) > 0:
	node = nodes_to_visit.pop()
	if not node:
	continue
	result.append(node.value)
	nodes_to_visit.append(node.left)
	nodes_to_visit.append(node.right)
	return result

	def Splay(self, key):
	"""Perform splay operation.

	Perform the splay operation for the given key. Moves the node with
	the given key to the top of the tree. If no node has the given
	key, the last node on the search path is moved to the top of the
	tree.

	This uses the simplified top-down splaying algorithm from:

	"Self-adjusting Binary Search Trees" by Sleator and Tarjan

	"""
	if self.IsEmpty():
	return
	# Create a dummy node. The use of the dummy node is a bit
	# counter-intuitive: The right child of the dummy node will hold
	# the L tree of the algorithm. The left child of the dummy node
	# will hold the R tree of the algorithm. Using a dummy node, left
	# and right will always be nodes and we avoid special cases.
	dummy = left = right = Node(None, None)
	current = self.root
	while True:
	if key < current.key:
	if not current.left:
	break
	if key < current.left.key:
	# Rotate right.
	tmp = current.left
	current.left = tmp.right
	tmp.right = current
	current = tmp
	if not current.left:
	break
	# Link right.
	right.left = current
	right = current
	current = current.left
	elif key > current.key:
	if not current.right:
	break
	if key > current.right.key:
	# Rotate left.
	tmp = current.right
	current.right = tmp.left
	tmp.left = current
	current = tmp
	if not current.right:
	break
	# Link left.
	left.right = current
	left = current
	current = current.right
	else:
	break
	# Assemble.
	left.right = current.left
	right.left = current.right
	current.left = dummy.right
	current.right = dummy.left
	self.root = current