Radix Tree
p
"""
A Radix Tree is a data structure that represents a space-optimized
trie (prefix tree) in whicheach node that is the only child is merged
with its parent [https://en.wikipedia.org/wiki/Radix_tree]
"""
class RadixNode:
def __init__(self, prefix: str = "", is_leaf: bool = False) -> None:
# Mapping from the first character of the prefix of the node
self.nodes: dict[str, RadixNode] = {}
# A node will be a leaf if the tree contains its word
self.is_leaf = is_leaf
self.prefix = prefix
def match(self, word: str) -> tuple[str, str, str]:
"""Compute the common substring of the prefix of the node and a word
Args:
word (str): word to compare
Returns:
(str, str, str): common substring, remaining prefix, remaining word
>>> RadixNode("myprefix").match("mystring")
('my', 'prefix', 'string')
"""
x = 0
for q, w in zip(self.prefix, word):
if q != w:
break
x += 1
return self.prefix[:x], self.prefix[x:], word[x:]
def insert_many(self, words: list[str]) -> None:
"""Insert many words in the tree
Args:
words (list[str]): list of words
>>> RadixNode("myprefix").insert_many(["mystring", "hello"])
"""
for word in words:
self.insert(word)
def insert(self, word: str) -> None:
"""Insert a word into the tree
Args:
word (str): word to insert
>>> RadixNode("myprefix").insert("mystring")
>>> root = RadixNode()
>>> root.insert_many(['myprefix', 'myprefixA', 'myprefixAA'])
>>> root.print_tree()
- myprefix (leaf)
-- A (leaf)
--- A (leaf)
"""
# Case 1: If the word is the prefix of the node
# Solution: We set the current node as leaf
if self.prefix == word and not self.is_leaf:
self.is_leaf = True
# Case 2: The node has no edges that have a prefix to the word
# Solution: We create an edge from the current node to a new one
# containing the word
elif word[0] not in self.nodes:
self.nodes[word[0]] = RadixNode(prefix=word, is_leaf=True)
else:
incoming_node = self.nodes[word[0]]
matching_string, remaining_prefix, remaining_word = incoming_node.match(
word
)
# Case 3: The node prefix is equal to the matching
# Solution: We insert remaining word on the next node
if remaining_prefix == "":
self.nodes[matching_string[0]].insert(remaining_word)
# Case 4: The word is greater equal to the matching
# Solution: Create a node in between both nodes, change
# prefixes and add the new node for the remaining word
else:
incoming_node.prefix = remaining_prefix
aux_node = self.nodes[matching_string[0]]
self.nodes[matching_string[0]] = RadixNode(matching_string, False)
self.nodes[matching_string[0]].nodes[remaining_prefix[0]] = aux_node
if remaining_word == "":
self.nodes[matching_string[0]].is_leaf = True
else:
self.nodes[matching_string[0]].insert(remaining_word)
def find(self, word: str) -> bool:
"""Returns if the word is on the tree
Args:
word (str): word to check
Returns:
bool: True if the word appears on the tree
>>> RadixNode("myprefix").find("mystring")
False
"""
incoming_node = self.nodes.get(word[0], None)
if not incoming_node:
return False
else:
matching_string, remaining_prefix, remaining_word = incoming_node.match(
word
)
# If there is remaining prefix, the word can't be on the tree
if remaining_prefix != "":
return False
# This applies when the word and the prefix are equal
elif remaining_word == "":
return incoming_node.is_leaf
# We have word remaining so we check the next node
else:
return incoming_node.find(remaining_word)
def delete(self, word: str) -> bool:
"""Deletes a word from the tree if it exists
Args:
word (str): word to be deleted
Returns:
bool: True if the word was found and deleted. False if word is not found
>>> RadixNode("myprefix").delete("mystring")
False
"""
incoming_node = self.nodes.get(word[0], None)
if not incoming_node:
return False
else:
matching_string, remaining_prefix, remaining_word = incoming_node.match(
word
)
# If there is remaining prefix, the word can't be on the tree
if remaining_prefix != "":
return False
# We have word remaining so we check the next node
elif remaining_word != "":
return incoming_node.delete(remaining_word)
# If it is not a leaf, we don't have to delete
elif not incoming_node.is_leaf:
return False
else:
# We delete the nodes if no edges go from it
if len(incoming_node.nodes) == 0:
del self.nodes[word[0]]
# We merge the current node with its only child
if len(self.nodes) == 1 and not self.is_leaf:
merging_node = next(iter(self.nodes.values()))
self.is_leaf = merging_node.is_leaf
self.prefix += merging_node.prefix
self.nodes = merging_node.nodes
# If there is more than 1 edge, we just mark it as non-leaf
elif len(incoming_node.nodes) > 1:
incoming_node.is_leaf = False
# If there is 1 edge, we merge it with its child
else:
merging_node = next(iter(incoming_node.nodes.values()))
incoming_node.is_leaf = merging_node.is_leaf
incoming_node.prefix += merging_node.prefix
incoming_node.nodes = merging_node.nodes
return True
def print_tree(self, height: int = 0) -> None:
"""Print the tree
Args:
height (int, optional): Height of the printed node
"""
if self.prefix != "":
print("-" * height, self.prefix, " (leaf)" if self.is_leaf else "")
for value in self.nodes.values():
value.print_tree(height + 1)
def test_trie() -> bool:
words = "banana bananas bandana band apple all beast".split()
root = RadixNode()
root.insert_many(words)
assert all(root.find(word) for word in words)
assert not root.find("bandanas")
assert not root.find("apps")
root.delete("all")
assert not root.find("all")
root.delete("banana")
assert not root.find("banana")
assert root.find("bananas")
return True
def pytests() -> None:
assert test_trie()
def main() -> None:
"""
>>> pytests()
"""
root = RadixNode()
words = "banana bananas bandanas bandana band apple all beast".split()
root.insert_many(words)
print("Words:", words)
print("Tree:")
root.print_tree()
if __name__ == "__main__":
main()
