bshyong/python_bst.py

## python_bst.py
class BSTnode(object):
    """
Representation of a node in a binary search tree.
Has a left child, right child, and key value, and stores its subtree size.
"""
    def __init__(self, parent, t):
        """Create a new leaf with key t."""
        self.key = t
        self.parent = parent
        self.left = None
        self.right = None
        self.size = 1

    def update_stats(self):
        """Updates this node's size based on its children's sizes."""
        self.size = (0 if self.left is None else self.left.size) + (0 if self.right is None else self.right.size)

    def insert(self, t, NodeType):
        """Insert key t into the subtree rooted at this node (updating subtree size)."""
        self.size += 1
        if t < self.key:
            if self.left is None:
                self.left = NodeType(self, t)
                return self.left
            else:
                return self.left.insert(t, NodeType)
        else:
            if self.right is None:
                self.right = NodeType(self, t)
                return self.right
            else:
                return self.right.insert(t, NodeType)

    def find(self, t):
        """Return the node for key t if it is in this tree, or None otherwise."""
        if t == self.key:
            return self
        elif t < self.key:
            if self.left is None:
                return None
            else:
                return self.left.find(t)
        else:
            if self.right is None:
                return None
            else:
                return self.right.find(t)

    def rank(self, t):
        """Return the number of keys <= t in the subtree rooted at this node."""
        left_size = 0 if self.left is None else self.left.size
        if t == self.key:
            return left_size + 1
        elif t < self.key:
            if self.left is None:
                return 0
            else:
                return self.left.rank(t)
        else:
            if self.right is None:
                return left_size + 1
            else:
                return self.right.rank(t) + left_size + 1

    def minimum(self):
        """Returns the node with the smallest key in the subtree rooted by this node."""
        current = self
        while current.left is not None:
            current = current.left
        return current


    def successor(self):
        """Returns the node with the smallest key larger than this node's key, or None if this has the largest key in the tree."""
        if self.right is not None:
            return self.right.minimum()
        current = self
        while current.parent is not None and current.parent.right is current:
            current = current.parent
        return current.parent

    def delete(self):
        """"Delete this node from the tree."""
        if self.left is None or self.right is None:
            if self is self.parent.left:
                self.parent.left = self.left or self.right
                if self.parent.left is not None:
                    self.parent.left.parent = self.parent
            else:
                self.parent.right = self.left or self.right
                if self.parent.right is not None:
                    self.parent.right.parent = self.parent
            current = self.parent
            while current.key is not None:
                current.update_stats()
                current = current.parent
            return self
        else:
            s = self.successor()
            self.key, s.key = s.key, self.key
            return s.delete()

    def check(self, lokey, hikey):
        """Checks that the subtree rooted at t is a valid BST and all keys are between (lokey, hikey)."""
        if lokey is not None and self.key <= lokey:
            raise "BST RI violation"
        if hikey is not None and self.key >= hikey:
            raise "BST RI violation"
        if self.left is not None:
            if self.left.parent is not self:
                raise "BST RI violation"
            self.left.check(lokey, self.key)
        if self.right is not None:
            if self.right.parent is not self:
                raise "BST RI violation"
            self.right.check(self.key, hikey)
        if self.size != 1 + (0 if self.left is None else self.left.size) + (0 if self.right is None else self.right.size):
            raise "BST RI violation"

    def __repr__(self):
        return "<BST Node, key:" + str(self.key) + ">"

class BST(object):
    """
Simple binary search tree implementation, augmented with subtree sizes.
This BST supports insert, find, and delete-min operations.
Each tree contains some (possibly 0) BSTnode objects, representing nodes,
and a pointer to the root.
"""

    def __init__(self, NodeType=BSTnode):
        self.root = None
        self.NodeType = NodeType
        self.psroot = self.NodeType(None, None)

    def reroot(self):
        self.root = self.psroot.left

    def insert(self, t):
        """Insert key t into this BST, modifying it in-place."""
        if self.root is None:
            self.psroot.left = self.NodeType(self.psroot, t)
            self.reroot()
            return self.root
        else:
            return self.root.insert(t, self.NodeType)

    def find(self, t):
        """Return the node for key t if is in the tree, or None otherwise."""
        if self.root is None:
            return None
        else:
            return self.root.find(t)

    def rank(self, t):
        """The number of keys <= t in the tree."""
        if self.root is None:
            return 0
        else:
            return self.root.rank(t)

    def delete(self, t):
        """Delete the node for key t if it is in the tree."""
        node = self.find(t)
        deleted = self.root.delete()
        self.reroot()
        return deleted

    def check(self):
        if self.root is not None:
            self.root.check(None, None)

    def __str__(self):
        if self.root is None: return '<empty tree>'
        def recurse(node):
            if node is None: return [], 0, 0
            label = str(node.key)
            left_lines, left_pos, left_width = recurse(node.left)
            right_lines, right_pos, right_width = recurse(node.right)
            middle = max(right_pos + left_width - left_pos + 1, len(label), 2)
            pos = left_pos + middle // 2
            width = left_pos + middle + right_width - right_pos
            while len(left_lines) < len(right_lines):
                left_lines.append(' ' * left_width)
            while len(right_lines) < len(left_lines):
                right_lines.append(' ' * right_width)
            if (middle - len(label)) % 2 == 1 and node.parent is not None and \
               node is node.parent.left and len(label) < middle:
                label += '.'
            label = label.center(middle, '.')
            if label[0] == '.': label = ' ' + label[1:]
            if label[-1] == '.': label = label[:-1] + ' '
            lines = [' ' * left_pos + label + ' ' * (right_width - right_pos),
                     ' ' * left_pos + '/' + ' ' * (middle-2) +
                     '\\' + ' ' * (right_width - right_pos)] + \
              [left_line + ' ' * (width - left_width - right_width) +
               right_line
               for left_line, right_line in zip(left_lines, right_lines)]
            return lines, pos, width
        return '\n'.join(recurse(self.root) [0])

test1 = range(0, 100, 10)
test2 = [31, 41, 59, 26, 53, 58, 97, 93, 23]
test3 = "algorithms"

def printsizes(node):
    if node is None:
        print "node is nil"
    else:
        print "node", node.key, "has a subtree of size", node.size

def test(args=None, BSTtype=BST):
    import random, sys
    if not args:
        args = sys.argv[1:]
    if not args:
        print 'usage: %s <number-of-random-items | item item item ...>' % \
              sys.argv[0]
        sys.exit()
    elif len(args) == 1:
        items = (random.randrange(100) for i in xrange(int(args[0])))
    else:
        items = [int(i) for i in args]

    tree = BSTtype()
    print tree
    for item in items:
        tree.insert(item)
        print
        print tree

if __name__ == '__main__': test()
	class BSTnode(object):
	"""
	Representation of a node in a binary search tree.
	Has a left child, right child, and key value, and stores its subtree size.
	"""
	def __init__(self, parent, t):
	"""Create a new leaf with key t."""
	self.key = t
	self.parent = parent
	self.left = None
	self.right = None
	self.size = 1

	def update_stats(self):
	"""Updates this node's size based on its children's sizes."""
	self.size = (0 if self.left is None else self.left.size) + (0 if self.right is None else self.right.size)

	def insert(self, t, NodeType):
	"""Insert key t into the subtree rooted at this node (updating subtree size)."""
	self.size += 1
	if t < self.key:
	if self.left is None:
	self.left = NodeType(self, t)
	return self.left
	else:
	return self.left.insert(t, NodeType)
	else:
	if self.right is None:
	self.right = NodeType(self, t)
	return self.right
	else:
	return self.right.insert(t, NodeType)

	def find(self, t):
	"""Return the node for key t if it is in this tree, or None otherwise."""
	if t == self.key:
	return self
	elif t < self.key:
	if self.left is None:
	return None
	else:
	return self.left.find(t)
	else:
	if self.right is None:
	return None
	else:
	return self.right.find(t)

	def rank(self, t):
	"""Return the number of keys <= t in the subtree rooted at this node."""
	left_size = 0 if self.left is None else self.left.size
	if t == self.key:
	return left_size + 1
	elif t < self.key:
	if self.left is None:
	return 0
	else:
	return self.left.rank(t)
	else:
	if self.right is None:
	return left_size + 1
	else:
	return self.right.rank(t) + left_size + 1

	def minimum(self):
	"""Returns the node with the smallest key in the subtree rooted by this node."""
	current = self
	while current.left is not None:
	current = current.left
	return current


	def successor(self):
	"""Returns the node with the smallest key larger than this node's key, or None if this has the largest key in the tree."""
	if self.right is not None:
	return self.right.minimum()
	current = self
	while current.parent is not None and current.parent.right is current:
	current = current.parent
	return current.parent

	def delete(self):
	""""Delete this node from the tree."""
	if self.left is None or self.right is None:
	if self is self.parent.left:
	self.parent.left = self.left or self.right
	if self.parent.left is not None:
	self.parent.left.parent = self.parent
	else:
	self.parent.right = self.left or self.right
	if self.parent.right is not None:
	self.parent.right.parent = self.parent
	current = self.parent
	while current.key is not None:
	current.update_stats()
	current = current.parent
	return self
	else:
	s = self.successor()
	self.key, s.key = s.key, self.key
	return s.delete()

	def check(self, lokey, hikey):
	"""Checks that the subtree rooted at t is a valid BST and all keys are between (lokey, hikey)."""
	if lokey is not None and self.key <= lokey:
	raise "BST RI violation"
	if hikey is not None and self.key >= hikey:
	raise "BST RI violation"
	if self.left is not None:
	if self.left.parent is not self:
	raise "BST RI violation"
	self.left.check(lokey, self.key)
	if self.right is not None:
	if self.right.parent is not self:
	raise "BST RI violation"
	self.right.check(self.key, hikey)
	if self.size != 1 + (0 if self.left is None else self.left.size) + (0 if self.right is None else self.right.size):
	raise "BST RI violation"

	def __repr__(self):
	return "<BST Node, key:" + str(self.key) + ">"

	class BST(object):
	"""
	Simple binary search tree implementation, augmented with subtree sizes.
	This BST supports insert, find, and delete-min operations.
	Each tree contains some (possibly 0) BSTnode objects, representing nodes,
	and a pointer to the root.
	"""

	def __init__(self, NodeType=BSTnode):
	self.root = None
	self.NodeType = NodeType
	self.psroot = self.NodeType(None, None)

	def reroot(self):
	self.root = self.psroot.left

	def insert(self, t):
	"""Insert key t into this BST, modifying it in-place."""
	if self.root is None:
	self.psroot.left = self.NodeType(self.psroot, t)
	self.reroot()
	return self.root
	else:
	return self.root.insert(t, self.NodeType)

	def find(self, t):
	"""Return the node for key t if is in the tree, or None otherwise."""
	if self.root is None:
	return None
	else:
	return self.root.find(t)

	def rank(self, t):
	"""The number of keys <= t in the tree."""
	if self.root is None:
	return 0
	else:
	return self.root.rank(t)

	def delete(self, t):
	"""Delete the node for key t if it is in the tree."""
	node = self.find(t)
	deleted = self.root.delete()
	self.reroot()
	return deleted

	def check(self):
	if self.root is not None:
	self.root.check(None, None)

	def __str__(self):
	if self.root is None: return '<empty tree>'
	def recurse(node):
	if node is None: return [], 0, 0
	label = str(node.key)
	left_lines, left_pos, left_width = recurse(node.left)
	right_lines, right_pos, right_width = recurse(node.right)
	middle = max(right_pos + left_width - left_pos + 1, len(label), 2)
	pos = left_pos + middle // 2
	width = left_pos + middle + right_width - right_pos
	while len(left_lines) < len(right_lines):
	left_lines.append(' ' * left_width)
	while len(right_lines) < len(left_lines):
	right_lines.append(' ' * right_width)
	if (middle - len(label)) % 2 == 1 and node.parent is not None and \
	node is node.parent.left and len(label) < middle:
	label += '.'
	label = label.center(middle, '.')
	if label[0] == '.': label = ' ' + label[1:]
	if label[-1] == '.': label = label[:-1] + ' '
	lines = [' ' * left_pos + label + ' ' * (right_width - right_pos),
	' ' * left_pos + '/' + ' ' * (middle-2) +
	'\\' + ' ' * (right_width - right_pos)] + \
	[left_line + ' ' * (width - left_width - right_width) +
	right_line
	for left_line, right_line in zip(left_lines, right_lines)]
	return lines, pos, width
	return '\n'.join(recurse(self.root) [0])

	test1 = range(0, 100, 10)
	test2 = [31, 41, 59, 26, 53, 58, 97, 93, 23]
	test3 = "algorithms"

	def printsizes(node):
	if node is None:
	print "node is nil"
	else:
	print "node", node.key, "has a subtree of size", node.size

	def test(args=None, BSTtype=BST):
	import random, sys
	if not args:
	args = sys.argv[1:]
	if not args:
	print 'usage: %s <number-of-random-items \| item item item ...>' % \
	sys.argv[0]
	sys.exit()
	elif len(args) == 1:
	items = (random.randrange(100) for i in xrange(int(args[0])))
	else:
	items = [int(i) for i in args]

	tree = BSTtype()
	print tree
	for item in items:
	tree.insert(item)
	print
	print tree

	if __name__ == '__main__': test()