--- title: "Gap Buffer" date: 2024-07-06T21:27:19+01:00 draft: false # I don't care for draft mode, git has branches for that description: "As featured in GNU Emacs" tags: - algorithms - data structures - python categories: - programming series: - Cool algorithms favorite: false disable_feed: false --- The [_Gap Buffer_][wiki] is a popular data structure for text editors to represent files and editable buffers. The most famous of them probably being [emacs]. [wiki]: https://en.wikipedia.org/wiki/Gap_buffer [emacs]: https://www.gnu.org/software/emacs/manual/html_node/elisp/Buffer-Gap.html ## What does it do? A _Gap Buffer_ is simply a list of characters, similar to a normal string, but with the added twist of splitting it into two side: the prefix and suffix, on either side of the cursor. In between them, a gap is left to allow for quick insertion at the cursor. Moving the cursor moves the gap around the buffer, the prefix and suffix getting shorter/longer as required. ## Implementation I'll be writing a sample implementation in Python, to keep with the rest of the series, This does not showcase the elegance of the _Gap Buffer_ in action like a C implementation full of `memmove`s would. ### Representation We'll be representing the gap buffer as an actual list of characters. Given that Python doesn't _have_ characters, wel'll have to settle for a list of strings, each representing a single character... ```python Char = str class GapBuffer: # List of characters, contains prefix and suffix of string with gap in the middle _buf: list[Char] # The gap is contained between [start, end) (i.e: buf[start:end]) _gap_start: int _gap_end: int # Visual representation of the gap buffer: # This is a very [ ]long string. # |<----------------------------------------------->| capacity # |<------------>| |<-------->| string # |<------------------->| gap # |<------------>| prefix # |<-------->| suffix def __init__(self, initial_capacity: int = 16) -> None: assert initial_capacity > 0 # Initialize an empty gap buffer self._buf = [""] * initial_capacity self._gap_start = 0 self._gap_end = initial_capacity ``` ### Accessors I'm mostly adding these for exposition, and making it easier to write `assert`s later. ```python @property def capacity(self) -> int: return len(self._buf) @property def gap_length(self) -> int: return self._gap_end - self._gap_start @property def string_length(self) -> int: return self.capacity - self.gap_length @property def prefix_length(self) -> int: return self._gap_start @property def suffix_length(self) -> int: return self.capacity - self._gap_end ``` ### Growing the buffer I've written this method in a somewhat non-idiomatic manner, to make it closer to how it would look in C using `realloc` instead. It would be more efficient to use slicing to insert the needed extra capacity directly, instead of making a new buffer and copying characters over. ```python def grow(self, capacity: int) -> None: assert capacity >= self.capacity # Create a new buffer with the new capacity new_buf = [""] * capacity # Move the prefix/suffix to their place in the new buffer added_capacity = capacity - len(self._buf) new_buf[: self._gap_start] = self._buf[: self._gap_start] new_buf[self._gap_end + added_capacity :] = self._buf[self._gap_end :] # Use the new buffer, account for added capacity self._buf = new_buf self._gap_end += added_capacity ``` ### Insertion Inserting text at the cursor's position means filling up the gap in the middle of the buffer. To do so we must first make sure that the gap is big enough, or grow the buffer accordingly. Then inserting the text is simply a matter of copying its characters in place, and moving the start of the gap further right. ```python def insert(self, val: str) -> None: # Ensure we have enouh space to insert the whole string if len(val) > self.gap_length: self.grow(max(self.capacity * 2, self.string_length + len(val))) # Fill the gap with the given string self._buf[self._gap_start : self._gap_start + len(val)] = val self._gap_start += len(val) ``` ### Deletion Removing text from the buffer simply expands the gap in the corresponding direction, shortening the string's prefix/suffix. This makes it very cheap. The methods are named after the `backspace` and `delete` keys on the keyboard. ```python def backspace(self, dist: int = 1) -> None: assert dist <= self.prefix_length # Extend gap to the left self._gap_start -= dist def delete(self, dist: int = 1) -> None: assert dist <= self.suffix_length # Extend gap to the right self._gap_end += dist ``` ### Moving the cursor Moving the cursor along the buffer will shift letters from one side of the gap to the other, moving them accross from prefix to suffix and back. I find Python's list slicing not quite as elegant to read as a `memmove`, though it does make for a very small and efficient implementation. ```python def left(self, dist: int = 1) -> None: assert dist <= self.prefix_length # Shift the needed number of characters from end of prefix to start of suffix self._buf[self._gap_end - dist : self._gap_end] = self._buf[ self._gap_start - dist : self._gap_start ] # Adjust indices accordingly self._gap_start -= dist self._gap_end -= dist def right(self, dist: int = 1) -> None: assert dist <= self.suffix_length # Shift the needed number of characters from start of suffix to end of prefix self._buf[self._gap_start : self._gap_start + dist] = self._buf[ self._gap_end : self._gap_end + dist ] # Adjust indices accordingly self._gap_start += dist self._gap_end += dist ```