2024-06-30 13:35:08 +02:00
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---
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title: "Trie"
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date: 2024-06-30T11:07:49+01:00
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draft: false # I don't care for draft mode, git has branches for that
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description: "A cool map"
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tags:
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- algorithms
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- data structures
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- python
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categories:
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- programming
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series:
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- Cool algorithms
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favorite: false
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disable_feed: false
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---
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This time, let's talk about the [_Trie_][wiki], which is a tree-based mapping
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structure most often used for string keys.
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[wiki]: https://en.wikipedia.org/wiki/Trie
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<!--more-->
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2024-06-30 13:36:17 +02:00
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## What does it do?
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A _Trie_ can be used to map a set of string keys to their corresponding values,
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without the need for a hash function. This also means you won't suffer from hash
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collisions, though the tree-based structure will probably translate to slower
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performance than a good hash table.
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A _Trie_ is especially useful to represent a dictionary of words in the case of
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spell correction, as it can easily be used to fuzzy match words under a given
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edit distance (think [Levenshtein distance])
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[Levenshtein distance]: https://en.wikipedia.org/wiki/Levenshtein_distance
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2024-06-30 13:36:42 +02:00
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## Implementation
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This implementation will be in Python for exposition purposes, even though
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it already has a built-in `dict`.
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### Representation
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Creating a new `Trie` is easy: the root node starts off empty and without any
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mapped values.
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```python
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class Trie[T]:
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_children: dict[str, Trie[T]]
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_value: T | None
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def __init__(self):
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# Each letter is mapped to a Trie
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self._children = defaultdict(Trie)
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# If we match a full string, we store the mapped value
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self._value = None
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```
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We're using a `defaultdict` for the children for ease of implementation in this
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post. In reality, I would encourage you exit early when you can't match a given
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character.
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The string key will be implicit by the position of a node in the tree: the empty
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string at the root, one-character strings as its direct children, etc...
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2024-06-30 13:37:04 +02:00
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### Search
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An exact match look-up is easily done: we go down the tree until we've exhausted
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the key. At that point we've either found a mapped value or not.
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```python
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def get(self, key: str) -> T | None:
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# Have we matched the full key?
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if not key:
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# Store the `T` if mapped, `None` otherwise
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return self._value
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# Otherwise, recurse on the child corresponding to the first letter
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return self._children[key[0]].get(key[1:])
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```
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2024-06-30 13:37:21 +02:00
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### Insertion
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Adding a new value to the _Trie_ is similar to a key lookup, only this time we
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store the new value instead of returning it.
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```python
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def insert(self, key: str, value: T) -> bool:
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# Have we matched the full key?
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if not key:
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# Check whether we're overwriting a previous mapping
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was_mapped = self._value is None
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# Store the corresponding value
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self._value = value
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# Return whether we've performed an overwrite
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return was_mapped
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# Otherwise, recurse on the child corresponding to the first letter
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return self._children[key[0]].insert(key[1:], value)
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```
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2024-06-30 13:37:48 +02:00
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### Removal
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Removal should also look familiar.
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```python
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def remove(self, key: str) -> bool:
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# Have we matched the full key?
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if not key:
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was_mapped = self._value is None
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# Remove the value
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self._value = None
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# Return whether it was mapped
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return was_mapped
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# Otherwise, recurse on the child corresponding to the first letter
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return self._children[key[0]].remove(key[1:])
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```
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2024-06-30 13:38:01 +02:00
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### Fuzzy matching
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Fuzzily matching a given word is where the real difficulty is: the key is to
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realize we can use the prefix-tree nature of a _Trie_ to avoid doing wasteful
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work.
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By leveraging the prefix visit order of the tree, we can build an iterative
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Levenshtein distance matrix, in much the same way one would do so in its
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[Dynamic Programming] implementation (see the [Wagner-Fisher algorithm]).
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[Dynamic Programming]: https://en.wikipedia.org/wiki/Dynamic_programming
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[Wagner-Fisher algorithm]: https://en.wikipedia.org/wiki/Wagner%E2%80%93Fischer_algorithm
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```python
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class FuzzyResult[T](NamedTuple):
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distance: int
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key: str
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value: T
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def get_fuzzy(self, key: str, max_distance: int = 0) -> Iterator[FuzzyResult[T]]:
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def helper(
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current_word: str,
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node: Trie[T],
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previous_row: list[int],
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) -> Iterator[tuple[int, T]]:
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# Iterative Levenshtein
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current_row = [previous_row[0] + 1]
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current_char = current_word[-1]
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for column, key_char in enumerate(key, start=1):
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insertion = current_row[column - 1] + 1
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deletion = previous_row[column] + 1
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replacement = previous_row[column - 1] + (key_char != current_char)
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current_row.append(min(insertion, deletion, replacement))
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# If we are under the max distance, match this node
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if (distance := current_row[-1]) <= max_distance and node._value != None:
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# Only if it has a value of course
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yield FuzzyResult(distance, current_word, node._value)
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# If we can potentially still match children, recurse
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if min(current_row) <= max_distance:
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for c, child in node._children.items():
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yield from helper(current_word + c, child, current_row)
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# Build the first row -- the edit distance from the empty string
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row = list(range(len(key) + 1))
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# Base case for the empty string
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if (distance := row[-1]) <= max_distance and self._value != None:
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yield FuzzyResult(distance, "", self._value)
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for c, child in self._children.items():
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yield from helper(c, child, row)
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```
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